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lmdb-clib-0.9.31: mdb.c

/** @file mdb.c
 *	@brief Lightning memory-mapped database library
 *
 *	A Btree-based database management library modeled loosely on the
 *	BerkeleyDB API, but much simplified.
 */
/*
 * Copyright 2011-2021 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
 * <http://www.OpenLDAP.org/license.html>.
 *
 * This code is derived from btree.c written by Martin Hedenfalk.
 *
 * Copyright (c) 2009, 2010 Martin Hedenfalk <martin@bzero.se>
 *
 * 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.
 */
#ifndef _GNU_SOURCE
#define _GNU_SOURCE 1
#endif
#if defined(MDB_VL32) || defined(__WIN64__)
#define _FILE_OFFSET_BITS 64
#endif
#ifdef _WIN32
#include <malloc.h>
#include <wchar.h> /* get wcscpy() */
#include <windows.h>

/* We use native NT APIs to setup the memory map, so that we can
 * let the DB file grow incrementally instead of always preallocating
 * the full size. These APIs are defined in <wdm.h> and <ntifs.h>
 * but those headers are meant for driver-level development and
 * conflict with the regular user-level headers, so we explicitly
 * declare them here. We get pointers to these functions from
 * NTDLL.DLL at runtime, to avoid buildtime dependencies on any
 * NTDLL import libraries.
 */
typedef NTSTATUS(WINAPI NtCreateSectionFunc)(
    OUT PHANDLE sh,
    IN ACCESS_MASK acc,
    IN void* oa OPTIONAL,
    IN PLARGE_INTEGER ms OPTIONAL,
    IN ULONG pp,
    IN ULONG aa,
    IN HANDLE fh OPTIONAL);

static NtCreateSectionFunc* NtCreateSection;

typedef enum _SECTION_INHERIT { ViewShare = 1, ViewUnmap = 2 } SECTION_INHERIT;

typedef NTSTATUS(WINAPI NtMapViewOfSectionFunc)(
    IN PHANDLE sh,
    IN HANDLE ph,
    IN OUT PVOID* addr,
    IN ULONG_PTR zbits,
    IN SIZE_T cs,
    IN OUT PLARGE_INTEGER off OPTIONAL,
    IN OUT PSIZE_T vs,
    IN SECTION_INHERIT ih,
    IN ULONG at,
    IN ULONG pp);

static NtMapViewOfSectionFunc* NtMapViewOfSection;

typedef NTSTATUS(WINAPI NtCloseFunc)(HANDLE h);

static NtCloseFunc* NtClose;

/** getpid() returns int; MinGW defines pid_t but MinGW64 typedefs it
 *  as int64 which is wrong. MSVC doesn't define it at all, so just
 *  don't use it.
 */
#define MDB_PID_T int
#define MDB_THR_T DWORD
#include <sys/stat.h>
#include <sys/types.h>
#ifdef __GNUC__
#include <sys/param.h>
#else
#define LITTLE_ENDIAN 1234
#define BIG_ENDIAN 4321
#define BYTE_ORDER LITTLE_ENDIAN
#ifndef SSIZE_MAX
#define SSIZE_MAX INT_MAX
#endif
#endif
#define MDB_OFF_T int64_t
#else
#include <sys/stat.h>
#include <sys/types.h>
#define MDB_PID_T pid_t
#define MDB_THR_T pthread_t
#include <sys/mman.h>
#include <sys/param.h>
#include <sys/uio.h>
#ifdef HAVE_SYS_FILE_H
#include <sys/file.h>
#endif
#include <fcntl.h>
#define MDB_OFF_T off_t
#endif

#if defined(__mips) && defined(__linux)
/* MIPS has cache coherency issues, requires explicit cache control */
#include <sys/cachectl.h>
#define CACHEFLUSH(addr, bytes, cache) cacheflush(addr, bytes, cache)
#else
#define CACHEFLUSH(addr, bytes, cache)
#endif

#if defined(__linux) && !defined(MDB_FDATASYNC_WORKS)
/** fdatasync is broken on ext3/ext4fs on older kernels, see
 *	description in #mdb_env_open2 comments. You can safely
 *	define MDB_FDATASYNC_WORKS if this code will only be run
 *	on kernels 3.6 and newer.
 */
#define BROKEN_FDATASYNC
#endif

#include <errno.h>
#include <inttypes.h>
#include <limits.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>

#ifdef _MSC_VER
#include <io.h>
typedef SSIZE_T ssize_t;
#else
#include <unistd.h>
#endif

#if defined(__sun) || defined(__ANDROID__)
/* Most platforms have posix_memalign, older may only have memalign */
#define HAVE_MEMALIGN 1
#include <malloc.h>
/* On Solaris, we need the POSIX sigwait function */
#if defined(__sun)
#define _POSIX_PTHREAD_SEMANTICS 1
#endif
#endif

#if !(defined(BYTE_ORDER) || defined(__BYTE_ORDER))
#include <netinet/in.h>
#include <resolv.h> /* defines BYTE_ORDER on HPUX and Solaris */
#endif

#if defined(__FreeBSD__) && defined(__FreeBSD_version) && \
    __FreeBSD_version >= 1100110
#define MDB_USE_POSIX_MUTEX 1
#define MDB_USE_ROBUST 1
#elif defined(__APPLE__) || defined(BSD) || defined(__FreeBSD_kernel__)
#if !(defined(MDB_USE_POSIX_MUTEX) || defined(MDB_USE_POSIX_SEM))
#define MDB_USE_SYSV_SEM 1
#endif
#if defined(__APPLE__)
#define MDB_FDATASYNC(fd) fcntl(fd, F_FULLFSYNC)
#else
#define MDB_FDATASYNC fsync
#endif
#elif defined(__ANDROID__)
#define MDB_FDATASYNC fsync
#endif

#ifndef _WIN32
#include <pthread.h>
#include <signal.h>
#ifdef MDB_USE_POSIX_SEM
#define MDB_USE_HASH 1
#include <semaphore.h>
#elif defined(MDB_USE_SYSV_SEM)
#include <sys/ipc.h>
#include <sys/sem.h>
#ifdef _SEM_SEMUN_UNDEFINED
union semun {
  int val;
  struct semid_ds* buf;
  unsigned short* array;
};
#endif /* _SEM_SEMUN_UNDEFINED */
#else
#define MDB_USE_POSIX_MUTEX 1
#endif /* MDB_USE_POSIX_SEM */
#endif /* !_WIN32 */

#if defined(_WIN32) + defined(MDB_USE_POSIX_SEM) + defined(MDB_USE_SYSV_SEM) + \
        defined(MDB_USE_POSIX_MUTEX) !=                                        \
    1
#error "Ambiguous shared-lock implementation"
#endif

#ifdef USE_VALGRIND
#include <valgrind/memcheck.h>
#define VGMEMP_CREATE(h, r, z) VALGRIND_CREATE_MEMPOOL(h, r, z)
#define VGMEMP_ALLOC(h, a, s) VALGRIND_MEMPOOL_ALLOC(h, a, s)
#define VGMEMP_FREE(h, a) VALGRIND_MEMPOOL_FREE(h, a)
#define VGMEMP_DESTROY(h) VALGRIND_DESTROY_MEMPOOL(h)
#define VGMEMP_DEFINED(a, s) VALGRIND_MAKE_MEM_DEFINED(a, s)
#else
#define VGMEMP_CREATE(h, r, z)
#define VGMEMP_ALLOC(h, a, s)
#define VGMEMP_FREE(h, a)
#define VGMEMP_DESTROY(h)
#define VGMEMP_DEFINED(a, s)
#endif

#ifndef BYTE_ORDER
#if (defined(_LITTLE_ENDIAN) || defined(_BIG_ENDIAN)) && \
    !(defined(_LITTLE_ENDIAN) && defined(_BIG_ENDIAN))
/* Solaris just defines one or the other */
#define LITTLE_ENDIAN 1234
#define BIG_ENDIAN 4321
#ifdef _LITTLE_ENDIAN
#define BYTE_ORDER LITTLE_ENDIAN
#else
#define BYTE_ORDER BIG_ENDIAN
#endif
#else
#define BYTE_ORDER __BYTE_ORDER
#endif
#endif

#ifndef LITTLE_ENDIAN
#define LITTLE_ENDIAN __LITTLE_ENDIAN
#endif
#ifndef BIG_ENDIAN
#define BIG_ENDIAN __BIG_ENDIAN
#endif

#if defined(__i386) || defined(__x86_64) || defined(_M_IX86)
#define MISALIGNED_OK 1
#endif

#include "lmdb.h"
#include "midl.h"

#if (BYTE_ORDER == LITTLE_ENDIAN) == (BYTE_ORDER == BIG_ENDIAN)
#error "Unknown or unsupported endianness (BYTE_ORDER)"
#elif (-6 & 5) || CHAR_BIT != 8 || UINT_MAX != 0xffffffff || \
    MDB_SIZE_MAX % UINT_MAX
#error "Two's complement, reasonably sized integer types, please"
#endif

#if (((__clang_major__ << 8) | __clang_minor__) >= 0x0302) || \
    (((__GNUC__ << 8) | __GNUC_MINOR__) >= 0x0403)
/** Mark infrequently used env functions as cold. This puts them in a separate
 *  section, and optimizes them for size */
#define ESECT __attribute__((cold))
#else
/* On older compilers, use a separate section */
#ifdef __GNUC__
#ifdef __APPLE__
#define ESECT __attribute__((section("__TEXT,text_env")))
#else
#define ESECT __attribute__((section("text_env")))
#endif
#else
#define ESECT
#endif
#endif

#ifdef _WIN32
#define CALL_CONV WINAPI
#else
#define CALL_CONV
#endif

/** @defgroup internal	LMDB Internals
 *	@{
 */
/** @defgroup compat	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.
 *	@{
 */

/** Features under development */
#ifndef MDB_DEVEL
#define MDB_DEVEL 0
#endif

/** Wrapper around __func__, which is a C99 feature */
#if __STDC_VERSION__ >= 199901L
#define mdb_func_ __func__
#elif __GNUC__ >= 2 || _MSC_VER >= 1300
#define mdb_func_ __FUNCTION__
#else
/* If a debug message says <mdb_unknown>(), update the #if statements above */
#define mdb_func_ "<mdb_unknown>"
#endif

/* Internal error codes, not exposed outside liblmdb */
#define MDB_NO_ROOT (MDB_LAST_ERRCODE + 10)
#ifdef _WIN32
#define MDB_OWNERDEAD ((int)WAIT_ABANDONED)
#elif defined MDB_USE_SYSV_SEM
#define MDB_OWNERDEAD (MDB_LAST_ERRCODE + 11)
#elif defined(MDB_USE_POSIX_MUTEX) && defined(EOWNERDEAD)
#define MDB_OWNERDEAD EOWNERDEAD /**< #LOCK_MUTEX0() result if dead owner */
#endif

#ifdef __GLIBC__
#define GLIBC_VER ((__GLIBC__ << 16) | __GLIBC_MINOR__)
#endif
/** Some platforms define the EOWNERDEAD error code
 * even though they don't support Robust Mutexes.
 * Compile with -DMDB_USE_ROBUST=0, or use some other
 * mechanism like -DMDB_USE_SYSV_SEM instead of
 * -DMDB_USE_POSIX_MUTEX. (SysV semaphores are
 * also Robust, but some systems don't support them
 * either.)
 */
#ifndef MDB_USE_ROBUST
/* Android currently lacks Robust Mutex support. So does glibc < 2.4. */
#if defined(MDB_USE_POSIX_MUTEX) && \
    (defined(__ANDROID__) || (defined(__GLIBC__) && GLIBC_VER < 0x020004))
#define MDB_USE_ROBUST 0
#else
#define MDB_USE_ROBUST 1
#endif
#endif /* !MDB_USE_ROBUST */

#if defined(MDB_USE_POSIX_MUTEX) && (MDB_USE_ROBUST)
/* glibc < 2.12 only provided _np API */
#if (defined(__GLIBC__) && GLIBC_VER < 0x02000c) || \
    (defined(PTHREAD_MUTEX_ROBUST_NP) && !defined(PTHREAD_MUTEX_ROBUST))
#define PTHREAD_MUTEX_ROBUST PTHREAD_MUTEX_ROBUST_NP
#define pthread_mutexattr_setrobust(attr, flag) \
  pthread_mutexattr_setrobust_np(attr, flag)
#define pthread_mutex_consistent(mutex) pthread_mutex_consistent_np(mutex)
#endif
#endif /* MDB_USE_POSIX_MUTEX && MDB_USE_ROBUST */

#if defined(MDB_OWNERDEAD) && (MDB_USE_ROBUST)
#define MDB_ROBUST_SUPPORTED 1
#endif

#ifdef _WIN32
#define MDB_USE_HASH 1
#define MDB_PIDLOCK 0
#define THREAD_RET DWORD
#define pthread_t HANDLE
#define pthread_mutex_t HANDLE
#define pthread_cond_t HANDLE
typedef HANDLE mdb_mutex_t, mdb_mutexref_t;
#define pthread_key_t DWORD
#define pthread_self() GetCurrentThreadId()
#define pthread_key_create(x, y) \
  ((*(x) = TlsAlloc()) == TLS_OUT_OF_INDEXES ? ErrCode() : 0)
#define pthread_key_delete(x) TlsFree(x)
#define pthread_getspecific(x) TlsGetValue(x)
#define pthread_setspecific(x, y) (TlsSetValue(x, y) ? 0 : ErrCode())
#define pthread_mutex_unlock(x) ReleaseMutex(*x)
#define pthread_mutex_lock(x) WaitForSingleObject(*x, INFINITE)
#define pthread_cond_signal(x) SetEvent(*x)
#define pthread_cond_wait(cond, mutex)                   \
  do {                                                   \
    SignalObjectAndWait(*mutex, *cond, INFINITE, FALSE); \
    WaitForSingleObject(*mutex, INFINITE);               \
  } while (0)
#define THREAD_CREATE(thr, start, arg) \
  (((thr) = CreateThread(NULL, 0, start, arg, 0, NULL)) ? 0 : ErrCode())
#define THREAD_FINISH(thr) (WaitForSingleObject(thr, INFINITE) ? ErrCode() : 0)
#define LOCK_MUTEX0(mutex) WaitForSingleObject(mutex, INFINITE)
#define UNLOCK_MUTEX(mutex) ReleaseMutex(mutex)
#define mdb_mutex_consistent(mutex) 0
#define getpid() GetCurrentProcessId()
#define MDB_FDATASYNC(fd) (!FlushFileBuffers(fd))
#define MDB_MSYNC(addr, len, flags) (!FlushViewOfFile(addr, len))
#define ErrCode() GetLastError()
#define GET_PAGESIZE(x)  \
  {                      \
    SYSTEM_INFO si;      \
    GetSystemInfo(&si);  \
    (x) = si.dwPageSize; \
  }
#define close(fd) (CloseHandle(fd) ? 0 : -1)
#define munmap(ptr, len) UnmapViewOfFile(ptr)
#ifdef PROCESS_QUERY_LIMITED_INFORMATION
#define MDB_PROCESS_QUERY_LIMITED_INFORMATION PROCESS_QUERY_LIMITED_INFORMATION
#else
#define MDB_PROCESS_QUERY_LIMITED_INFORMATION 0x1000
#endif
#else
#define THREAD_RET void*
#define THREAD_CREATE(thr, start, arg) pthread_create(&thr, NULL, start, arg)
#define THREAD_FINISH(thr) pthread_join(thr, NULL)

/** For MDB_LOCK_FORMAT: True if readers take a pid lock in the lockfile */
#define MDB_PIDLOCK 1

#ifdef MDB_USE_POSIX_SEM

typedef sem_t *mdb_mutex_t, *mdb_mutexref_t;
#define LOCK_MUTEX0(mutex) mdb_sem_wait(mutex)
#define UNLOCK_MUTEX(mutex) sem_post(mutex)

static int mdb_sem_wait(sem_t* sem) {
  int rc;
  while ((rc = sem_wait(sem)) && (rc = errno) == EINTR)
    ;
  return rc;
}

#elif defined MDB_USE_SYSV_SEM

typedef struct mdb_mutex {
  int semid;
  int semnum;
  int* locked;
} mdb_mutex_t[1], *mdb_mutexref_t;

#define LOCK_MUTEX0(mutex) mdb_sem_wait(mutex)
#define UNLOCK_MUTEX(mutex)              \
  do {                                   \
    struct sembuf sb = {0, 1, SEM_UNDO}; \
    sb.sem_num = (mutex)->semnum;        \
    *(mutex)->locked = 0;                \
    semop((mutex)->semid, &sb, 1);       \
  } while (0)

static int mdb_sem_wait(mdb_mutexref_t sem) {
  int rc, *locked = sem->locked;
  struct sembuf sb = {0, -1, SEM_UNDO};
  sb.sem_num = sem->semnum;
  do {
    if (!semop(sem->semid, &sb, 1)) {
      rc = *locked ? MDB_OWNERDEAD : MDB_SUCCESS;
      *locked = 1;
      break;
    }
  } while ((rc = errno) == EINTR);
  return rc;
}

#define mdb_mutex_consistent(mutex) 0

#else /* MDB_USE_POSIX_MUTEX: */
/** Shared mutex/semaphore as the original is stored.
 *
 *	Not for copies.  Instead it can be assigned to an #mdb_mutexref_t.
 *	When mdb_mutexref_t is a pointer and mdb_mutex_t is not, then it
 *	is array[size 1] so it can be assigned to the pointer.
 */
typedef pthread_mutex_t mdb_mutex_t[1];
/** Reference to an #mdb_mutex_t */
typedef pthread_mutex_t* mdb_mutexref_t;
/** Lock the reader or writer mutex.
 *	Returns 0 or a code to give #mdb_mutex_failed(), as in #LOCK_MUTEX().
 */
#define LOCK_MUTEX0(mutex) pthread_mutex_lock(mutex)
/** Unlock the reader or writer mutex.
 */
#define UNLOCK_MUTEX(mutex) pthread_mutex_unlock(mutex)
/** Mark mutex-protected data as repaired, after death of previous owner.
 */
#define mdb_mutex_consistent(mutex) pthread_mutex_consistent(mutex)
#endif /* MDB_USE_POSIX_SEM || MDB_USE_SYSV_SEM */

/** 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))
// #define	GET_PAGESIZE(x)	((x) = 65536)
#endif

#define Z MDB_FMT_Z /**< printf/scanf format modifier for size_t */
#define Yu MDB_PRIy(u) /**< printf format for #mdb_size_t */
#define Yd MDB_PRIy(d) /**< printf format for 'signed #mdb_size_t' */

#ifdef MDB_USE_SYSV_SEM
#define MNAME_LEN (sizeof(int))
#else
#define MNAME_LEN (sizeof(pthread_mutex_t))
#endif

/** Initial part of #MDB_env.me_mutexname[].
 *	Changes to this code must be reflected in #MDB_LOCK_FORMAT.
 */
#ifdef _WIN32
#define MUTEXNAME_PREFIX "Global\\MDB"
#elif defined MDB_USE_POSIX_SEM
#define MUTEXNAME_PREFIX "/MDB"
#endif

/** @} */

#ifdef MDB_ROBUST_SUPPORTED
/** Lock mutex, handle any error, set rc = result.
 *	Return 0 on success, nonzero (not rc) on error.
 */
#define LOCK_MUTEX(rc, env, mutex) \
  (((rc) = LOCK_MUTEX0(mutex)) && ((rc) = mdb_mutex_failed(env, mutex, rc)))
static int mdb_mutex_failed(MDB_env* env, mdb_mutexref_t mutex, int rc);
#else
#define LOCK_MUTEX(rc, env, mutex) ((rc) = LOCK_MUTEX0(mutex))
#define mdb_mutex_failed(env, mutex, rc) (rc)
#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.
 */
#ifndef MDB_DSYNC
#ifdef O_DSYNC
#define MDB_DSYNC O_DSYNC
#else
#define MDB_DSYNC O_SYNC
#endif
#endif
#endif

/** Function for flushing the data of a file. Define this to fsync
 *	if fdatasync() is not supported.
 */
#ifndef MDB_FDATASYNC
#define MDB_FDATASYNC fdatasync
#endif

#ifndef MDB_MSYNC
#define MDB_MSYNC(addr, len, flags) msync(addr, len, flags)
#endif

#ifndef MS_SYNC
#define MS_SYNC 1
#endif

#ifndef MS_ASYNC
#define MS_ASYNC 0
#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 MDB_ID pgno_t;

/** A transaction ID.
 *	See struct MDB_txn.mt_txnid for details.
 */
typedef MDB_ID txnid_t;

/** @defgroup debug	Debug Macros
 *	@{
 */
#ifndef MDB_DEBUG
/**	Enable debug output.  Needs variable argument macros (a C99 feature).
 *	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 MDB_DEBUG 0
#endif

#define MDB_DBG_INFO 1
#define MDB_DBG_TRACE 2

#if MDB_DEBUG
static int mdb_debug = MDB_DBG_TRACE;
static txnid_t mdb_debug_start;

/**	Print a debug message with printf formatting.
 *	Requires double parenthesis around 2 or more args.
 */
#define DPRINTF(args) ((void)((mdb_debug & MDB_DBG_INFO) && DPRINTF0 args))
#define DPRINTF0(fmt, ...) \
  fprintf(stderr, "%s:%d " fmt "\n", mdb_func_, __LINE__, __VA_ARGS__)
/** Trace info for replaying */
#define MDB_TRACE(args) ((void)((mdb_debug & MDB_DBG_TRACE) && DPRINTF1 args))
#define DPRINTF1(fmt, ...) \
  fprintf(stderr, ">%d:%s: " fmt "\n", getpid(), mdb_func_, __VA_ARGS__)
#else
#define DPRINTF(args) ((void)0)
#define MDB_TRACE(args) ((void)0)
#endif
/**	Print a debug string.
 *	The string is printed literally, with no format processing.
 */
#define DPUTS(arg) DPRINTF(("%s", arg))
/** Debugging output value of a cursor DBI: Negative in a sub-cursor. */
#define DDBI(mc) \
  (((mc)->mc_flags & C_SUB) ? -(int)(mc)->mc_dbi : (int)(mc)->mc_dbi)
/** @} */

/**	@brief The maximum size of a database page.
 *
 *	It is 32k or 64k, since value-PAGEBASE must fit in
 *	#MDB_page.%mp_upper.
 *
 *	LMDB will use database pages < OS pages if needed.
 *	That causes more I/O in write transactions: The OS must
 *	know (read) the whole page before writing a partial page.
 *
 *	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 MAX_PAGESIZE (PAGEBASE ? 0x10000 : 0x8000)

/** 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 LMDB 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 datafile format. */
#define MDB_DATA_VERSION ((MDB_DEVEL) ? 999 : 1)
/**	The version number for a database's lockfile format. */
#define MDB_LOCK_VERSION ((MDB_DEVEL) ? 999 : 2)
/** Number of bits representing #MDB_LOCK_VERSION in #MDB_LOCK_FORMAT.
 *	The remaining bits must leave room for #MDB_lock_desc.
 */
#define MDB_LOCK_VERSION_BITS 12

/**	@brief The max size of a key we can write, or 0 for computed max.
 *
 *	This macro should normally be left alone or set to 0.
 *	Note that a database with big keys or dupsort data cannot be
 *	reliably modified by a liblmdb which uses a smaller max.
 *	The default is 511 for backwards compat, or 0 when #MDB_DEVEL.
 *
 *	Other values are allowed, for backwards compat.  However:
 *	A value bigger than the computed max can break if you do not
 *	know what you are doing, and liblmdb <= 0.9.10 can break when
 *	modifying a DB with keys/dupsort data bigger than its max.
 *
 *	Data items in an #MDB_DUPSORT database are also limited to
 *	this size, since they're actually keys of a sub-DB.  Keys and
 *	#MDB_DUPSORT data items must fit on a node in a regular page.
 */
#ifndef MDB_MAXKEYSIZE
#define MDB_MAXKEYSIZE ((MDB_DEVEL) ? 0 : 511)
#endif

/**	The maximum size of a key we can write to the environment. */
#if MDB_MAXKEYSIZE
#define ENV_MAXKEY(env) (MDB_MAXKEYSIZE)
#else
#define ENV_MAXKEY(env) ((env)->me_maxkey)
#endif

/**	@brief The maximum size of a data item.
 *
 *	We only store a 32 bit value for node sizes.
 */
#define MAXDATASIZE 0xffffffffUL

#if MDB_DEBUG
/**	Key size which fits in a #DKBUF.
 *	@ingroup debug
 */
#define DKBUF_MAXKEYSIZE ((MDB_MAXKEYSIZE) > 0 ? (MDB_MAXKEYSIZE) : 511)
/**	A key buffer.
 *	@ingroup debug
 *	This is used for printing a hex dump of a key's contents.
 */
#define DKBUF char kbuf[DKBUF_MAXKEYSIZE * 2 + 1]
/**	A data value buffer.
 *	@ingroup debug
 *	This is used for printing a hex dump of a #MDB_DUPSORT value's contents.
 */
#define DDBUF char dbuf[DKBUF_MAXKEYSIZE * 2 + 1 + 2]
/**	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 DDBUF
#define DKEY(x) 0
#endif

/** An invalid page number.
 *	Mainly used to denote an empty tree.
 */
#define P_INVALID (~(pgno_t)0)

/** Test if the flags \b f are set in a flag word \b w. */
#define F_ISSET(w, f) (((w) & (f)) == (f))

/** Round \b n up to an even number. */
#define EVEN(n) (((n) + 1U) & -2) /* sign-extending -2 to match n+1U */

/** Least significant 1-bit of \b n.  n must be of an unsigned type. */
#define LOW_BIT(n) ((n) & (-(n)))

/** (log2(\b p2) % \b n), for p2 = power of 2 and 0 < n < 8. */
#define LOG2_MOD(p2, n) (7 - 86 / ((p2) % ((1U << (n)) - 1) + 11))
/* Explanation: Let p2 = 2**(n*y + x), x<n and M = (1U<<n)-1. Now p2 =
 * (M+1)**y * 2**x = 2**x (mod M). Finally "/" "happens" to return 7-x.
 */

/** Should be alignment of \b type. Ensure it is a power of 2. */
#define ALIGNOF2(type) \
  LOW_BIT(offsetof(    \
      struct {         \
        char ch_;      \
        type align_;   \
      },               \
      align_))

/**	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;

typedef unsigned long long mdb_hash_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.
 *
 *	If #MDB_NOTLS is set, the slot address is not saved in thread-specific
 * data.
 *
 *	No reader table is used if the database is on a read-only filesystem, or
 *	if #MDB_NOLOCK is set.
 *
 *	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.
 *	@{
 */
/**	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 {
  /**	Current Transaction ID when this transaction began, or (txnid_t)-1.
   *	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.
   */
  volatile txnid_t mrb_txnid;
  /** The process ID of the process owning this reader txn. */
  volatile MDB_PID_T mrb_pid;
  /** The thread ID of the thread owning this txn. */
  volatile MDB_THR_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 is also used on
 *	MacOSX/Darwin (using named semaphores) since MacOSX doesn't support
 *	process-shared POSIX mutexes. For these cases where a named object
 *	is used, the object name is derived from a 64 bit FNV hash of the
 *	environment pathname. As such, naming collisions are extremely
 *	unlikely. If a collision occurs, the results are unpredictable.
 */
typedef struct MDB_txbody {
  /** Stamp identifying this as an LMDB file. It must be set
   *	to #MDB_MAGIC. */
  uint32_t mtb_magic;
  /** Format of this lock file. Must be set to #MDB_LOCK_FORMAT. */
  uint32_t mtb_format;
  /**	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.
   */
  volatile txnid_t 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.
   */
  volatile unsigned mtb_numreaders;
#if defined(_WIN32) || defined(MDB_USE_POSIX_SEM)
  /** Binary form of names of the reader/writer locks */
  mdb_hash_t mtb_mutexid;
#elif defined(MDB_USE_SYSV_SEM)
  int mtb_semid;
  int mtb_rlocked;
#else
  /** Mutex protecting access to this table.
   *	This is the reader table lock used with LOCK_MUTEX().
   */
  mdb_mutex_t mtb_rmutex;
#endif
} MDB_txbody;

/** The actual reader table definition. */
typedef struct MDB_txninfo {
  union {
    MDB_txbody mtb;
#define mti_magic mt1.mtb.mtb_magic
#define mti_format mt1.mtb.mtb_format
#define mti_rmutex mt1.mtb.mtb_rmutex
#define mti_txnid mt1.mtb.mtb_txnid
#define mti_numreaders mt1.mtb.mtb_numreaders
#define mti_mutexid mt1.mtb.mtb_mutexid
#ifdef MDB_USE_SYSV_SEM
#define mti_semid mt1.mtb.mtb_semid
#define mti_rlocked mt1.mtb.mtb_rlocked
#endif
    char pad[(sizeof(MDB_txbody) + CACHELINE - 1) & ~(CACHELINE - 1)];
  } mt1;
#if !(defined(_WIN32) || defined(MDB_USE_POSIX_SEM))
  union {
#ifdef MDB_USE_SYSV_SEM
    int mt2_wlocked;
#define mti_wlocked mt2.mt2_wlocked
#else
    mdb_mutex_t mt2_wmutex;
#define mti_wmutex mt2.mt2_wmutex
#endif
    char pad[(MNAME_LEN + CACHELINE - 1) & ~(CACHELINE - 1)];
  } mt2;
#endif
  MDB_reader mti_readers[1];
} MDB_txninfo;

/** Lockfile format signature: version, features and field layout */
#define MDB_LOCK_FORMAT                                              \
  ((uint32_t)(((MDB_LOCK_VERSION) % (1U << MDB_LOCK_VERSION_BITS)) + \
              MDB_lock_desc * (1U << MDB_LOCK_VERSION_BITS)))

/** Lock type and layout. Values 0-119. _WIN32 implies #MDB_PIDLOCK.
 *	Some low values are reserved for future tweaks.
 */
#ifdef _WIN32
#define MDB_LOCK_TYPE (0 + ALIGNOF2(mdb_hash_t) / 8 % 2)
#elif defined MDB_USE_POSIX_SEM
#define MDB_LOCK_TYPE (4 + ALIGNOF2(mdb_hash_t) / 8 % 2)
#elif defined MDB_USE_SYSV_SEM
#define MDB_LOCK_TYPE (8)
#elif defined MDB_USE_POSIX_MUTEX
/* We do not know the inside of a POSIX mutex and how to check if mutexes
 * used by two executables are compatible. Just check alignment and size.
 */
#define MDB_LOCK_TYPE                            \
  (10 + LOG2_MOD(ALIGNOF2(pthread_mutex_t), 5) + \
   sizeof(pthread_mutex_t) / 4U % 22 * 5)
#endif

enum {
  /** Magic number for lockfile layout and features.
   *
   *  This *attempts* to stop liblmdb variants compiled with conflicting
   *	options from using the lockfile at the same time and thus breaking
   *	it.  It describes locking types, and sizes and sometimes alignment
   *	of the various lockfile items.
   *
   *	The detected ranges are mostly guesswork, or based simply on how
   *	big they could be without using more bits.  So we can tweak them
   *	in good conscience when updating #MDB_LOCK_VERSION.
   */
  MDB_lock_desc =
      /* Default CACHELINE=64 vs. other values (have seen mention of 32-256) */
  (CACHELINE == 64 ? 0 : 1 + LOG2_MOD(CACHELINE >> (CACHELINE > 64), 5)) +
      6 * (sizeof(MDB_PID_T) / 4 % 3) /* legacy(2) to word(4/8)? */
      + 18 * (sizeof(pthread_t) / 4 % 5) /* can be struct{id, active data} */
      + 90 * (sizeof(MDB_txbody) / CACHELINE % 3) +
      270 * (MDB_LOCK_TYPE % 120)
      /* The above is < 270*120 < 2**15 */
      + ((sizeof(txnid_t) == 8) << 15) /* 32bit/64bit */
      + ((sizeof(MDB_reader) > CACHELINE) << 16)
      /* Not really needed - implied by MDB_LOCK_TYPE != (_WIN32 locking) */
      + (((MDB_PIDLOCK) != 0) << 17)
  /* 18 bits total: Must be <= (32 - MDB_LOCK_VERSION_BITS). */
};
/** @} */

/** Common header for all page types. The page type depends on #mp_flags.
 *
 * #P_BRANCH and #P_LEAF pages have unsorted '#MDB_node's at the end, with
 * sorted #mp_ptrs[] entries referring to them. Exception: #P_LEAF2 pages
 * omit mp_ptrs and pack sorted #MDB_DUPFIXED values after the page header.
 *
 * #P_OVERFLOW records occupy one or more contiguous pages where only the
 * first has a page header. They hold the real data of #F_BIGDATA nodes.
 *
 * #P_SUBP sub-pages are small leaf "pages" with duplicate data.
 * A node with flag #F_DUPDATA but not #F_SUBDATA contains a sub-page.
 * (Duplicate data can also go in sub-databases, which use normal pages.)
 *
 * #P_META pages contain #MDB_meta, the start point of an LMDB snapshot.
 *
 * Each non-metapage up to #MDB_meta.%mm_last_pg is reachable exactly once
 * in the snapshot: Either used by a database or listed in a freeDB record.
 */
typedef struct MDB_page {
#define mp_pgno mp_p.p_pgno
#define mp_next mp_p.p_next
  union {
    pgno_t p_pgno; /**< page number */
    struct MDB_page* p_next; /**< for in-memory list of freed pages */
  } mp_p;
  uint16_t mp_pad; /**< key size if this is a LEAF2 page */
/**	@defgroup mdb_page	Page Flags
 *	@ingroup internal
 *	Flags for the page headers.
 *	@{
 */
#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, also set for #P_SUBP pages */
#define P_LEAF2 0x20 /**< for #MDB_DUPFIXED records */
#define P_SUBP 0x40 /**< for #MDB_DUPSORT sub-pages */
#define P_LOOSE 0x4000 /**< page was dirtied then freed, can be reused */
#define P_KEEP 0x8000 /**< leave this page alone during spill */
  /** @} */
  uint16_t mp_flags; /**< @ref mdb_page */
#define mp_lower mp_pb.pb.pb_lower
#define mp_upper mp_pb.pb.pb_upper
#define mp_pages mp_pb.pb_pages
  union {
    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[0]; /**< dynamic size */
} MDB_page;

/** Alternate page header, for 2-byte aligned access */
typedef struct MDB_page2 {
  uint16_t mp2_p[sizeof(pgno_t) / 2];
  uint16_t mp2_pad;
  uint16_t mp2_flags;
  indx_t mp2_lower;
  indx_t mp2_upper;
  indx_t mp2_ptrs[0];
} MDB_page2;

#define MP_PGNO(p) (((MDB_page2*)(void*)(p))->mp2_p)
#define MP_PAD(p) (((MDB_page2*)(void*)(p))->mp2_pad)
#define MP_FLAGS(p) (((MDB_page2*)(void*)(p))->mp2_flags)
#define MP_LOWER(p) (((MDB_page2*)(void*)(p))->mp2_lower)
#define MP_UPPER(p) (((MDB_page2*)(void*)(p))->mp2_upper)
#define MP_PTRS(p) (((MDB_page2*)(void*)(p))->mp2_ptrs)

/** 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))

/** ITS#7713, change PAGEBASE to handle 65536 byte pages */
#define PAGEBASE PAGEHDRSZ
// #define	PAGEBASE	((MDB_DEVEL) ? PAGEHDRSZ : 0)

/** Number of nodes on a page */
#define NUMKEYS(p) ((MP_LOWER(p) - (PAGEHDRSZ - PAGEBASE)) >> 1)

/** The amount of space remaining in the page */
#define SIZELEFT(p) (indx_t)(MP_UPPER(p) - MP_LOWER(p))

/** 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(MP_FLAGS(p), P_LEAF)
/** Test if a page is a LEAF2 page */
#define IS_LEAF2(p) F_ISSET(MP_FLAGS(p), P_LEAF2)
/** Test if a page is a branch page */
#define IS_BRANCH(p) F_ISSET(MP_FLAGS(p), P_BRANCH)
/** Test if a page is an overflow page */
#define IS_OVERFLOW(p) F_ISSET(MP_FLAGS(p), P_OVERFLOW)
/** Test if a page is a sub page */
#define IS_SUBP(p) F_ISSET(MP_FLAGS(p), P_SUBP)

/** The number of overflow pages needed to store the given size. */
#define OVPAGES(size, psize) ((PAGEHDRSZ - 1 + (size)) / (psize) + 1)

/** Link in #MDB_txn.%mt_loose_pgs list.
 *  Kept outside the page header, which is needed when reusing the page.
 */
#define NEXT_LOOSE_PAGE(p) (*(MDB_page**)((p) + 2))

/** Header for a single key/data pair within a page.
 * Used in pages of type #P_BRANCH and #P_LEAF without #P_LEAF2.
 * We guarantee 2-byte alignment for 'MDB_node's.
 *
 * #mn_lo and #mn_hi are used for data size on leaf nodes, and for child
 * pgno on branch nodes.  On 64 bit platforms, #mn_flags is also used
 * for pgno.  (Branch nodes have no flags).  Lo and hi are in host byte
 * order in case some accesses can be optimized to 32-bit word access.
 *
 * Leaf node flags describe node contents.  #F_BIGDATA says the node's
 * data part is the page number of an overflow page with actual data.
 * #F_DUPDATA and #F_SUBDATA can be combined giving duplicate data in
 * a sub-page/sub-database, and named databases (just #F_SUBDATA).
 */
typedef struct MDB_node {
  /** part of data size or pgno
   *	@{ */
#if BYTE_ORDER == LITTLE_ENDIAN
  unsigned short mn_lo, mn_hi;
#else
  unsigned short mn_hi, mn_lo;
#endif
  /** @} */
/** @defgroup mdb_node Node Flags
 *	@ingroup internal
 *	Flags for node headers.
 *	@{
 */
#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 */

/** valid flags for #mdb_node_add() */
#define NODE_ADD_FLAGS (F_DUPDATA | F_SUBDATA | MDB_RESERVE | MDB_APPEND)

  /** @} */
  unsigned short mn_flags; /**< @ref mdb_node */
  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)

/** Bit position of top word in page number, for shifting mn_flags */
#define PGNO_TOPWORD ((pgno_t) - 1 > 0xffffffffu ? 32 : 0)

/** 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) + MP_PTRS(p)[i] + PAGEBASE))

/** 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 */
#define NODEPGNO(node)                             \
  ((node)->mn_lo | ((pgno_t)(node)->mn_hi << 16) | \
   (PGNO_TOPWORD ? ((pgno_t)(node)->mn_flags << PGNO_TOPWORD) : 0))
/** Set the page number in a branch node */
#define SETPGNO(node, pgno)                      \
  do {                                           \
    (node)->mn_lo = (pgno) & 0xffff;             \
    (node)->mn_hi = (pgno) >> 16;                \
    if (PGNO_TOPWORD)                            \
      (node)->mn_flags = (pgno) >> PGNO_TOPWORD; \
  } while (0)

/** 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)

/** Copy a page number from src to dst */
#ifdef MISALIGNED_OK
#define COPY_PGNO(dst, src) dst = src
#undef MP_PGNO
#define MP_PGNO(p) ((p)->mp_pgno)
#else
#if MDB_SIZE_MAX > 0xffffffffU
#define COPY_PGNO(dst, src)      \
  do {                           \
    unsigned short *s, *d;       \
    s = (unsigned short*)&(src); \
    d = (unsigned short*)&(dst); \
    *d++ = *s++;                 \
    *d++ = *s++;                 \
    *d++ = *s++;                 \
    *d = *s;                     \
  } while (0)
#else
#define COPY_PGNO(dst, src)      \
  do {                           \
    unsigned short *s, *d;       \
    s = (unsigned short*)&(src); \
    d = (unsigned short*)&(dst); \
    *d++ = *s++;                 \
    *d = *s;                     \
  } while (0)
#endif
#endif
/** 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 keyptr, if requested. */
#define MDB_GET_KEY(node, keyptr)        \
  {                                      \
    if ((keyptr) != NULL) {              \
      (keyptr)->mv_size = NODEKSZ(node); \
      (keyptr)->mv_data = NODEKEY(node); \
    }                                    \
  }

/** Set the \b node's key into \b key. */
#define MDB_GET_KEY2(node, key)  \
  {                              \
    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_dbi_open */
  uint16_t md_depth; /**< depth of this tree */
  pgno_t md_branch_pages; /**< number of internal pages */
  pgno_t md_leaf_pages; /**< number of leaf pages */
  pgno_t md_overflow_pages; /**< number of overflow pages */
  mdb_size_t md_entries; /**< number of data items */
  pgno_t md_root; /**< the root page of this tree */
} MDB_db;

#define MDB_VALID 0x8000 /**< DB handle is valid, for me_dbflags */
#define PERSISTENT_FLAGS (0xffff & ~(MDB_VALID))
/** #mdb_dbi_open() flags */
#define VALID_FLAGS                                               \
  (MDB_REVERSEKEY | MDB_DUPSORT | MDB_INTEGERKEY | MDB_DUPFIXED | \
   MDB_INTEGERDUP | MDB_REVERSEDUP | MDB_CREATE)

/** Handle for the DB used to track free pages. */
#define FREE_DBI 0
/** Handle for the default DB. */
#define MAIN_DBI 1
/** Number of DBs in metapage (free and main) - also hardcoded elsewhere */
#define CORE_DBS 2

/** Number of meta pages - also hardcoded elsewhere */
#define NUM_METAS 2

/** Meta page content.
 *	A meta page is the start point for accessing a database snapshot.
 *	Pages 0-1 are meta pages. Transaction N writes meta page #(N % 2).
 */
typedef struct MDB_meta {
  /** Stamp identifying this as an LMDB file. It must be set
   *	to #MDB_MAGIC. */
  uint32_t mm_magic;
  /** Version number of this file. Must be set to #MDB_DATA_VERSION. */
  uint32_t mm_version;
#ifdef MDB_VL32
  union { /* always zero since we don't support fixed mapping in MDB_VL32 */
    MDB_ID mmun_ull;
    void* mmun_address;
  } mm_un;
#define mm_address mm_un.mmun_address
#else
  void* mm_address; /**< address for fixed mapping */
#endif
  mdb_size_t mm_mapsize; /**< size of mmap region */
  MDB_db mm_dbs[CORE_DBS]; /**< first is free space, 2nd is main db */
  /** The size of pages used in this DB */
#define mm_psize mm_dbs[FREE_DBI].md_pad
  /** Any persistent environment flags. @ref mdb_env */
#define mm_flags mm_dbs[FREE_DBI].md_flags
  /** Last used page in the datafile.
   *	Actually the file may be shorter if the freeDB lists the final pages.
   */
  pgno_t mm_last_pg;
  volatile txnid_t mm_txnid; /**< txnid that committed this page */
} MDB_meta;

/** Buffer for a stack-allocated meta page.
 *	The members define size and alignment, and silence type
 *	aliasing warnings.  They are not used directly; that could
 *	mean incorrectly using several union members in parallel.
 */
typedef union MDB_metabuf {
  MDB_page mb_page;
  struct {
    char mm_pad[PAGEHDRSZ];
    MDB_meta mm_meta;
  } mb_metabuf;
} MDB_metabuf;

/** Auxiliary DB info.
 *	The information here is mostly static/read-only. There is
 *	only a single copy of this record in the environment.
 */
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 */
  void* md_relctx; /**< user-provided context for md_rel */
} MDB_dbx;

/** A database transaction.
 *	Every operation requires a transaction handle.
 */
struct MDB_txn {
  MDB_txn* mt_parent; /**< parent of a nested txn */
  /** Nested txn under this txn, set together with flag #MDB_TXN_HAS_CHILD */
  MDB_txn* mt_child;
  pgno_t mt_next_pgno; /**< next unallocated page */
#ifdef MDB_VL32
  pgno_t mt_last_pgno; /**< last written page */
#endif
  /** 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.
   */
  txnid_t mt_txnid;
  MDB_env* mt_env; /**< the DB environment */
  /** The list of pages that became unused during this transaction.
   */
  MDB_IDL mt_free_pgs;
  /** The list of loose pages that became unused and may be reused
   *	in this transaction, linked through #NEXT_LOOSE_PAGE(page).
   */
  MDB_page* mt_loose_pgs;
  /** Number of loose pages (#mt_loose_pgs) */
  int mt_loose_count;
  /** The sorted list of dirty pages we temporarily wrote to disk
   *	because the dirty list was full. page numbers in here are
   *	shifted left by 1, deleted slots have the LSB set.
   */
  MDB_IDL mt_spill_pgs;
  union {
    /** For write txns: Modified pages. Sorted when not MDB_WRITEMAP. */
    MDB_ID2L dirty_list;
    /** For read txns: This thread/txn's reader table slot, or NULL. */
    MDB_reader* reader;
  } 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;
  /** Array of sequence numbers for each DB handle */
  unsigned int* mt_dbiseqs;
/** @defgroup mt_dbflag	Transaction DB Flags
 *	@ingroup internal
 * @{
 */
#define DB_DIRTY 0x01 /**< DB was written in this txn */
#define DB_STALE 0x02 /**< Named-DB record is older than txnID */
#define DB_NEW 0x04 /**< Named-DB handle opened in this txn */
#define DB_VALID 0x08 /**< DB handle is valid, see also #MDB_VALID */
#define DB_USRVALID 0x10 /**< As #DB_VALID, but not set for #FREE_DBI */
#define DB_DUPDATA 0x20 /**< DB is #MDB_DUPSORT data */
  /** @} */
  /** In write txns, array of cursors for each DB */
  MDB_cursor** mt_cursors;
  /** Array of flags for each DB */
  unsigned char* mt_dbflags;
#ifdef MDB_VL32
  /** List of read-only pages (actually chunks) */
  MDB_ID3L mt_rpages;
  /** We map chunks of 16 pages. Even though Windows uses 4KB pages, all
   * mappings must begin on 64KB boundaries. So we round off all pgnos to
   * a chunk boundary. We do the same on Linux for symmetry, and also to
   * reduce the frequency of mmap/munmap calls.
   */
#define MDB_RPAGE_CHUNK 16
#define MDB_TRPAGE_SIZE 4096 /**< size of #mt_rpages array of chunks */
#define MDB_TRPAGE_MAX (MDB_TRPAGE_SIZE - 1) /**< maximum chunk index */
  unsigned int mt_rpcheck; /**< threshold for reclaiming unref'd chunks */
#endif
  /**	Number of DB records in use, or 0 when the txn is finished.
   *	This number only ever increments until the txn finishes; we
   *	don't decrement it when individual DB handles are closed.
   */
  MDB_dbi mt_numdbs;

  /** @defgroup mdb_txn	Transaction Flags
   *	@ingroup internal
   *	@{
   */
  /** #mdb_txn_begin() flags */
#define MDB_TXN_BEGIN_FLAGS (MDB_NOMETASYNC | MDB_NOSYNC | MDB_RDONLY)
#define MDB_TXN_NOMETASYNC \
  MDB_NOMETASYNC /**< don't sync meta for this txn on commit */
#define MDB_TXN_NOSYNC MDB_NOSYNC /**< don't sync this txn on commit */
#define MDB_TXN_RDONLY MDB_RDONLY /**< read-only transaction */
  /* internal txn flags */
#define MDB_TXN_WRITEMAP MDB_WRITEMAP /**< copy of #MDB_env flag in writers */
#define MDB_TXN_FINISHED 0x01 /**< txn is finished or never began */
#define MDB_TXN_ERROR 0x02 /**< txn is unusable after an error */
#define MDB_TXN_DIRTY 0x04 /**< must write, even if dirty list is empty */
#define MDB_TXN_SPILLS 0x08 /**< txn or a parent has spilled pages */
#define MDB_TXN_HAS_CHILD 0x10 /**< txn has an #MDB_txn.%mt_child */
  /** most operations on the txn are currently illegal */
#define MDB_TXN_BLOCKED (MDB_TXN_FINISHED | MDB_TXN_ERROR | MDB_TXN_HAS_CHILD)
  /** @} */
  unsigned int mt_flags; /**< @ref mdb_txn */
  /** #dirty_list room: Array size - \#dirty pages visible to this txn.
   *	Includes ancestor txns' dirty pages not hidden by other txns'
   *	dirty/spilled pages. Thus commit(nested txn) has room to merge
   *	dirty_list into mt_parent after freeing hidden mt_parent pages.
   */
  unsigned int mt_dirty_room;
};

/** 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.
 *	A cursor holds a path of (page pointer, key index) from the DB
 *	root to a position in the DB, plus other state. #MDB_DUPSORT
 *	cursors include an xcursor to the current data item. Write txns
 *	track their cursors and keep them up to date when data moves.
 *	Exception: An xcursor's pointer to a #P_SUBP page can be stale.
 *	(A node with #F_DUPDATA but no #F_SUBDATA contains a subpage).
 */
struct MDB_cursor {
  /** Next cursor on this DB in this txn */
  MDB_cursor* mc_next;
  /** Backup of the original cursor if this cursor is a shadow */
  MDB_cursor* mc_backup;
  /** 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;
  /** The database record for this cursor */
  MDB_db* mc_db;
  /** The database auxiliary record for this cursor */
  MDB_dbx* mc_dbx;
  /** The @ref mt_dbflag for this database */
  unsigned char* mc_dbflag;
  unsigned short mc_snum; /**< number of pushed pages */
  unsigned short mc_top; /**< index of top page, normally mc_snum-1 */
/** @defgroup mdb_cursor	Cursor Flags
 *	@ingroup internal
 *	Cursor state flags.
 *	@{
 */
#define C_INITIALIZED 0x01 /**< cursor has been initialized and is valid */
#define C_EOF 0x02 /**< No more data */
#define C_SUB 0x04 /**< Cursor is a sub-cursor */
#define C_DEL 0x08 /**< last op was a cursor_del */
#define C_UNTRACK 0x40 /**< Un-track cursor when closing */
#define C_WRITEMAP MDB_TXN_WRITEMAP /**< Copy of txn flag */
/** Read-only cursor into the txn's original snapshot in the map.
 *	Set for read-only txns, and in #mdb_page_alloc() for #FREE_DBI when
 *	#MDB_DEVEL & 2. Only implements code which is necessary for this.
 */
#define C_ORIG_RDONLY MDB_TXN_RDONLY
  /** @} */
  unsigned int mc_flags; /**< @ref mdb_cursor */
  MDB_page* mc_pg[CURSOR_STACK]; /**< stack of pushed pages */
  indx_t mc_ki[CURSOR_STACK]; /**< stack of page indices */
#ifdef MDB_VL32
  MDB_page* mc_ovpg; /**< a referenced overflow page */
#define MC_OVPG(mc) ((mc)->mc_ovpg)
#define MC_SET_OVPG(mc, pg) ((mc)->mc_ovpg = (pg))
#else
#define MC_OVPG(mc) ((MDB_page*)0)
#define MC_SET_OVPG(mc, pg) ((void)0)
#endif
};

/** 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;
  /** The database record for this Dup DB */
  MDB_db mx_db;
  /**	The auxiliary DB record for this Dup DB */
  MDB_dbx mx_dbx;
  /** The @ref mt_dbflag for this Dup DB */
  unsigned char mx_dbflag;
} MDB_xcursor;

/** Check if there is an inited xcursor */
#define XCURSOR_INITED(mc) \
  ((mc)->mc_xcursor && ((mc)->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED))

/** Update the xcursor's sub-page pointer, if any, in \b mc.  Needed
 *	when the node which contains the sub-page may have moved.  Called
 *	with leaf page \b mp = mc->mc_pg[\b top].
 */
#define XCURSOR_REFRESH(mc, top, mp)                                \
  do {                                                              \
    MDB_page* xr_pg = (mp);                                         \
    MDB_node* xr_node;                                              \
    if (!XCURSOR_INITED(mc) || (mc)->mc_ki[top] >= NUMKEYS(xr_pg))  \
      break;                                                        \
    xr_node = NODEPTR(xr_pg, (mc)->mc_ki[top]);                     \
    if ((xr_node->mn_flags & (F_DUPDATA | F_SUBDATA)) == F_DUPDATA) \
      (mc)->mc_xcursor->mx_cursor.mc_pg[0] = NODEDATA(xr_node);     \
  } while (0)

/** State of FreeDB old pages, stored in the MDB_env */
typedef struct MDB_pgstate {
  pgno_t* mf_pghead; /**< Reclaimed freeDB pages, or NULL before use */
  txnid_t mf_pglast; /**< ID of last used record, or 0 if !mf_pghead */
} MDB_pgstate;

/** The database environment. */
struct MDB_env {
  HANDLE me_fd; /**< The main data file */
  HANDLE me_lfd; /**< The lock file */
  HANDLE me_mfd; /**< For writing and syncing the meta pages */
#ifdef _WIN32
#ifdef MDB_VL32
  HANDLE me_fmh; /**< File Mapping handle */
#endif /* MDB_VL32 */
  HANDLE me_ovfd; /**< Overlapped/async with write-through file handle */
#endif /* _WIN32 */
  /** Failed to update the meta page. Probably an I/O error. */
#define MDB_FATAL_ERROR 0x80000000U
  /** Some fields are initialized. */
#define MDB_ENV_ACTIVE 0x20000000U
  /** me_txkey is set */
#define MDB_ENV_TXKEY 0x10000000U
  /** fdatasync is unreliable */
#define MDB_FSYNCONLY 0x08000000U
  uint32_t me_flags; /**< @ref mdb_env */
  unsigned int me_psize; /**< DB page size, inited from me_os_psize */
  unsigned int me_os_psize; /**< OS page size, from #GET_PAGESIZE */
  unsigned int me_maxreaders; /**< size of the reader table */
  /** Max #MDB_txninfo.%mti_numreaders of interest to #mdb_env_close() */
  volatile int me_close_readers;
  MDB_dbi me_numdbs; /**< number of DBs opened */
  MDB_dbi me_maxdbs; /**< size of the DB table */
  MDB_PID_T me_pid; /**< process ID of this env */
  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 or NULL */
  MDB_meta* me_metas[NUM_METAS]; /**< pointers to the two meta pages */
  void* me_pbuf; /**< scratch area for DUPSORT put() */
  MDB_txn* me_txn; /**< current write transaction */
  MDB_txn* me_txn0; /**< prealloc'd write transaction */
  mdb_size_t me_mapsize; /**< size of the data memory map */
  MDB_OFF_T me_size; /**< current file size */
  pgno_t me_maxpg; /**< me_mapsize / me_psize */
  MDB_dbx* me_dbxs; /**< array of static DB info */
  uint16_t* me_dbflags; /**< array of flags from MDB_db.md_flags */
  unsigned int* me_dbiseqs; /**< array of dbi sequence numbers */
  pthread_key_t me_txkey; /**< thread-key for readers */
  txnid_t me_pgoldest; /**< ID of oldest reader last time we looked */
  MDB_pgstate me_pgstate; /**< state of old pages from freeDB */
#define me_pglast me_pgstate.mf_pglast
#define me_pghead me_pgstate.mf_pghead
  MDB_page* me_dpages; /**< list of malloc'd blocks for re-use */
  /** IDL of pages that became unused in a write txn */
  MDB_IDL me_free_pgs;
  /** ID2L of pages written during a write txn. Length MDB_IDL_UM_SIZE. */
  MDB_ID2L me_dirty_list;
  /** Max number of freelist items that can fit in a single overflow page */
  int me_maxfree_1pg;
  /** Max size of a node on a page */
  unsigned int me_nodemax;
#if !(MDB_MAXKEYSIZE)
  unsigned int me_maxkey; /**< max size of a key */
#endif
  int me_live_reader; /**< have liveness lock in reader table */
#ifdef _WIN32
  int me_pidquery; /**< Used in OpenProcess */
  OVERLAPPED* ov; /**< Used for for overlapping I/O requests */
  int ovs; /**< Count of OVERLAPPEDs */
#endif
#ifdef MDB_USE_POSIX_MUTEX /* Posix mutexes reside in shared mem */
#define me_rmutex me_txns->mti_rmutex /**< Shared reader lock */
#define me_wmutex me_txns->mti_wmutex /**< Shared writer lock */
#else
  mdb_mutex_t me_rmutex;
  mdb_mutex_t me_wmutex;
#if defined(_WIN32) || defined(MDB_USE_POSIX_SEM)
  /** Half-initialized name of mutexes, to be completed by #MUTEXNAME() */
  char me_mutexname[sizeof(MUTEXNAME_PREFIX) + 11];
#endif
#endif
#ifdef MDB_VL32
  MDB_ID3L me_rpages; /**< like #mt_rpages, but global to env */
  pthread_mutex_t me_rpmutex; /**< control access to #me_rpages */
#define MDB_ERPAGE_SIZE 16384
#define MDB_ERPAGE_MAX (MDB_ERPAGE_SIZE - 1)
  unsigned int me_rpcheck;
#endif
  void* me_userctx; /**< User-settable context */
  MDB_assert_func* me_assert_func; /**< Callback for assertion failures */
};

/** Nested transaction */
typedef struct MDB_ntxn {
  MDB_txn mnt_txn; /**< the transaction */
  MDB_pgstate mnt_pgstate; /**< parent transaction's saved freestate */
} MDB_ntxn;

/** max number of pages to commit in one writev() call */
#define MDB_COMMIT_PAGES 64
#if defined(IOV_MAX) && IOV_MAX < MDB_COMMIT_PAGES
#undef MDB_COMMIT_PAGES
#define MDB_COMMIT_PAGES IOV_MAX
#endif

/** max bytes to write in one call */
#define MAX_WRITE (0x40000000U >> (sizeof(ssize_t) == 4))

/** Check \b txn and \b dbi arguments to a function */
#define TXN_DBI_EXIST(txn, dbi, validity) \
  ((txn) && (dbi) < (txn)->mt_numdbs && ((txn)->mt_dbflags[dbi] & (validity)))

/** Check for misused \b dbi handles */
#define TXN_DBI_CHANGED(txn, dbi) \
  ((txn)->mt_dbiseqs[dbi] != (txn)->mt_env->me_dbiseqs[dbi])

static int mdb_page_alloc(MDB_cursor* mc, int num, MDB_page** mp);
static int mdb_page_new(MDB_cursor* mc, uint32_t flags, int num, MDB_page** mp);
static int mdb_page_touch(MDB_cursor* mc);

#define MDB_END_NAMES \
  {"committed",       \
   "empty-commit",    \
   "abort",           \
   "reset",           \
   "reset-tmp",       \
   "fail-begin",      \
   "fail-beginchild"}
enum {
  /* mdb_txn_end operation number, for logging */
  MDB_END_COMMITTED,
  MDB_END_EMPTY_COMMIT,
  MDB_END_ABORT,
  MDB_END_RESET,
  MDB_END_RESET_TMP,
  MDB_END_FAIL_BEGIN,
  MDB_END_FAIL_BEGINCHILD
};
#define MDB_END_OPMASK 0x0F /**< mask for #mdb_txn_end() operation number */
#define MDB_END_UPDATE 0x10 /**< update env state (DBIs) */
#define MDB_END_FREE 0x20 /**< free txn unless it is #MDB_env.%me_txn0 */
#define MDB_END_SLOT MDB_NOTLS /**< release any reader slot if #MDB_NOTLS */
static void mdb_txn_end(MDB_txn* txn, unsigned mode);

static int mdb_page_get(MDB_cursor* mc, pgno_t pgno, MDB_page** mp, int* lvl);
static int mdb_page_search_root(MDB_cursor* mc, MDB_val* key, int modify);
#define MDB_PS_MODIFY 1
#define MDB_PS_ROOTONLY 2
#define MDB_PS_FIRST 4
#define MDB_PS_LAST 8
static int mdb_page_search(MDB_cursor* mc, MDB_val* key, int flags);
static int mdb_page_merge(MDB_cursor* csrc, MDB_cursor* cdst);

#define MDB_SPLIT_REPLACE MDB_APPENDDUP /**< newkey is not new */
static int mdb_page_split(
    MDB_cursor* mc,
    MDB_val* newkey,
    MDB_val* newdata,
    pgno_t newpgno,
    unsigned int nflags);

static int mdb_env_read_header(MDB_env* env, int prev, MDB_meta* meta);
static MDB_meta* mdb_env_pick_meta(const MDB_env* env);
static int mdb_env_write_meta(MDB_txn* txn);
#if defined(MDB_USE_POSIX_MUTEX) && \
    !defined(MDB_ROBUST_SUPPORTED) /* Drop unused excl arg */
#define mdb_env_close0(env, excl) mdb_env_close1(env)
#endif
static void mdb_env_close0(MDB_env* env, int excl);

static MDB_node* mdb_node_search(MDB_cursor* mc, MDB_val* key, int* exactp);
static int mdb_node_add(
    MDB_cursor* mc,
    indx_t indx,
    MDB_val* key,
    MDB_val* data,
    pgno_t pgno,
    unsigned int flags);
static void mdb_node_del(MDB_cursor* mc, int ksize);
static void mdb_node_shrink(MDB_page* mp, indx_t indx);
static int mdb_node_move(MDB_cursor* csrc, MDB_cursor* cdst, int fromleft);
static int mdb_node_read(MDB_cursor* mc, MDB_node* leaf, MDB_val* data);
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 int mdb_rebalance(MDB_cursor* mc);
static int mdb_update_key(MDB_cursor* mc, MDB_val* key);

static void mdb_cursor_pop(MDB_cursor* mc);
static int mdb_cursor_push(MDB_cursor* mc, MDB_page* mp);

static int _mdb_cursor_del(MDB_cursor* mc, unsigned int flags);
static int _mdb_cursor_put(
    MDB_cursor* mc,
    MDB_val* key,
    MDB_val* data,
    unsigned int flags);

static int mdb_cursor_del0(MDB_cursor* mc);
static int mdb_del0(
    MDB_txn* txn,
    MDB_dbi dbi,
    MDB_val* key,
    MDB_val* data,
    unsigned flags);
static int mdb_cursor_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_cursor_init(MDB_cursor* mc, MDB_txn* txn, MDB_dbi dbi, MDB_xcursor* mx);
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, MDB_xcursor* src_mx, int force);

static int mdb_drop0(MDB_cursor* mc, int subs);
static void mdb_default_cmp(MDB_txn* txn, MDB_dbi dbi);
static int mdb_reader_check0(MDB_env* env, int rlocked, int* dead);

/** @cond */
static MDB_cmp_func mdb_cmp_memn, mdb_cmp_memnr, mdb_cmp_int, mdb_cmp_cint,
    mdb_cmp_long;
/** @endcond */

/** Compare two items pointing at '#mdb_size_t's of unknown alignment. */
#ifdef MISALIGNED_OK
#define mdb_cmp_clong mdb_cmp_long
#else
#define mdb_cmp_clong mdb_cmp_cint
#endif

/** True if we need #mdb_cmp_clong() instead of \b cmp for #MDB_INTEGERDUP */
#define NEED_CMP_CLONG(cmp, ksize)                    \
  (UINT_MAX < MDB_SIZE_MAX && (cmp) == mdb_cmp_int && \
   (ksize) == sizeof(mdb_size_t))

#ifdef _WIN32
static SECURITY_DESCRIPTOR mdb_null_sd;
static SECURITY_ATTRIBUTES mdb_all_sa;
static int mdb_sec_inited;

struct MDB_name;
static int utf8_to_utf16(const char* src, struct MDB_name* dst, int xtra);
#endif

/** Return the library version info. */
char* ESECT 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 LMDB @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 or environment had fatal error",
    "MDB_VERSION_MISMATCH: Database environment version mismatch",
    "MDB_INVALID: File is not an LMDB file",
    "MDB_MAP_FULL: Environment mapsize limit reached",
    "MDB_DBS_FULL: Environment maxdbs limit reached",
    "MDB_READERS_FULL: Environment maxreaders limit reached",
    "MDB_TLS_FULL: Thread-local storage keys full - too many environments open",
    "MDB_TXN_FULL: Transaction has too many dirty pages - transaction too big",
    "MDB_CURSOR_FULL: Internal error - cursor stack limit reached",
    "MDB_PAGE_FULL: Internal error - page has no more space",
    "MDB_MAP_RESIZED: Database contents grew beyond environment mapsize",
    "MDB_INCOMPATIBLE: Operation and DB incompatible, or DB flags changed",
    "MDB_BAD_RSLOT: Invalid reuse of reader locktable slot",
    "MDB_BAD_TXN: Transaction must abort, has a child, or is invalid",
    "MDB_BAD_VALSIZE: Unsupported size of key/DB name/data, or wrong DUPFIXED size",
    "MDB_BAD_DBI: The specified DBI handle was closed/changed unexpectedly",
    "MDB_PROBLEM: Unexpected problem - txn should abort",
};

char* mdb_strerror(int err) {
#ifdef _WIN32
  /** HACK: pad 4KB on stack over the buf. Return system msgs in buf.
   *	This works as long as no function between the call to mdb_strerror
   *	and the actual use of the message uses more than 4K of stack.
   */
#define MSGSIZE 1024
#define PADSIZE 4096
  char buf[MSGSIZE + PADSIZE], *ptr = buf;
#endif
  int i;
  if (!err)
    return ("Successful return: 0");

  if (err >= MDB_KEYEXIST && err <= MDB_LAST_ERRCODE) {
    i = err - MDB_KEYEXIST;
    return mdb_errstr[i];
  }

#ifdef _WIN32
  /* These are the C-runtime error codes we use. The comment indicates
   * their numeric value, and the Win32 error they would correspond to
   * if the error actually came from a Win32 API. A major mess, we should
   * have used LMDB-specific error codes for everything.
   */
  switch (err) {
    case ENOENT: /* 2, FILE_NOT_FOUND */
    case EIO: /* 5, ACCESS_DENIED */
    case ENOMEM: /* 12, INVALID_ACCESS */
    case EACCES: /* 13, INVALID_DATA */
    case EBUSY: /* 16, CURRENT_DIRECTORY */
    case EINVAL: /* 22, BAD_COMMAND */
    case ENOSPC: /* 28, OUT_OF_PAPER */
      return strerror(err);
    default:;
  }
  buf[0] = 0;
  FormatMessageA(
      FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS,
      NULL,
      err,
      0,
      ptr,
      MSGSIZE,
      NULL);
  return ptr;
#else
  if (err < 0)
    return "Invalid error code";
  return strerror(err);
#endif
}

/** assert(3) variant in cursor context */
#define mdb_cassert(mc, expr) mdb_assert0((mc)->mc_txn->mt_env, expr, #expr)
/** assert(3) variant in transaction context */
#define mdb_tassert(txn, expr) mdb_assert0((txn)->mt_env, expr, #expr)
/** assert(3) variant in environment context */
#define mdb_eassert(env, expr) mdb_assert0(env, expr, #expr)

#ifndef NDEBUG
#define mdb_assert0(env, expr, expr_txt) \
  ((expr) ? (void)0                      \
          : mdb_assert_fail(env, expr_txt, mdb_func_, __FILE__, __LINE__))

static void ESECT mdb_assert_fail(
    MDB_env* env,
    const char* expr_txt,
    const char* func,
    const char* file,
    int line) {
  char buf[400];
  sprintf(
      buf,
      "%.100s:%d: Assertion '%.200s' failed in %.40s()",
      file,
      line,
      expr_txt,
      func);
  if (env->me_assert_func)
    env->me_assert_func(env, buf);
  fprintf(stderr, "%s\n", buf);
  abort();
}
#else
#define mdb_assert0(env, expr, expr_txt) ((void)0)
#endif /* NDEBUG */

#if MDB_DEBUG
/** Return the page number of \b mp which may be sub-page, for debug output */
static pgno_t mdb_dbg_pgno(MDB_page* mp) {
  pgno_t ret;
  COPY_PGNO(ret, MP_PGNO(mp));
  return ret;
}

/** 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)
    return "";

  if (key->mv_size > DKBUF_MAXKEYSIZE)
    return "MDB_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
  buf[0] = '\0';
  for (i = 0; i < key->mv_size; i++)
    ptr += sprintf(ptr, "%02x", *c++);
#else
  sprintf(buf, "%.*s", key->mv_size, key->mv_data);
#endif
  return buf;
}

static char* mdb_dval(MDB_txn* txn, MDB_dbi dbi, MDB_val* data, char* buf) {
  if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) {
    mdb_dkey(data, buf + 1);
    *buf = '[';
    strcpy(buf + data->mv_size * 2 + 1, "]");
  } else
    *buf = '\0';
  return buf;
}

static const char* mdb_leafnode_type(MDB_node* n) {
  static char* const tp[2][2] = {{"", ": DB"}, {": sub-page", ": sub-DB"}};
  return F_ISSET(n->mn_flags, F_BIGDATA)
      ? ": overflow page"
      : tp[F_ISSET(n->mn_flags, F_DUPDATA)][F_ISSET(n->mn_flags, F_SUBDATA)];
}

/** Display all the keys in the page. */
void mdb_page_list(MDB_page* mp) {
  pgno_t pgno = mdb_dbg_pgno(mp);
  const char *type, *state = (MP_FLAGS(mp) & P_DIRTY) ? ", dirty" : "";
  MDB_node* node;
  unsigned int i, nkeys, nsize, total = 0;
  MDB_val key;
  DKBUF;

  switch (MP_FLAGS(mp) &
          (P_BRANCH | P_LEAF | P_LEAF2 | P_META | P_OVERFLOW | P_SUBP)) {
    case P_BRANCH:
      type = "Branch page";
      break;
    case P_LEAF:
      type = "Leaf page";
      break;
    case P_LEAF | P_SUBP:
      type = "Sub-page";
      break;
    case P_LEAF | P_LEAF2:
      type = "LEAF2 page";
      break;
    case P_LEAF | P_LEAF2 | P_SUBP:
      type = "LEAF2 sub-page";
      break;
    case P_OVERFLOW:
      fprintf(
          stderr,
          "Overflow page %" Yu " pages %u%s\n",
          pgno,
          mp->mp_pages,
          state);
      return;
    case P_META:
      fprintf(
          stderr,
          "Meta-page %" Yu " txnid %" Yu "\n",
          pgno,
          ((MDB_meta*)METADATA(mp))->mm_txnid);
      return;
    default:
      fprintf(stderr, "Bad page %" Yu " flags 0x%X\n", pgno, MP_FLAGS(mp));
      return;
  }

  nkeys = NUMKEYS(mp);
  fprintf(stderr, "%s %" Yu " numkeys %d%s\n", type, pgno, nkeys, state);

  for (i = 0; i < nkeys; i++) {
    if (IS_LEAF2(mp)) { /* LEAF2 pages have no mp_ptrs[] or node headers */
      key.mv_size = nsize = mp->mp_pad;
      key.mv_data = LEAF2KEY(mp, i, nsize);
      total += nsize;
      fprintf(stderr, "key %d: nsize %d, %s\n", i, nsize, DKEY(&key));
      continue;
    }
    node = NODEPTR(mp, i);
    key.mv_size = node->mn_ksize;
    key.mv_data = node->mn_data;
    nsize = NODESIZE + key.mv_size;
    if (IS_BRANCH(mp)) {
      fprintf(
          stderr, "key %d: page %" Yu ", %s\n", i, NODEPGNO(node), DKEY(&key));
      total += nsize;
    } else {
      if (F_ISSET(node->mn_flags, F_BIGDATA))
        nsize += sizeof(pgno_t);
      else
        nsize += NODEDSZ(node);
      total += nsize;
      nsize += sizeof(indx_t);
      fprintf(
          stderr,
          "key %d: nsize %d, %s%s\n",
          i,
          nsize,
          DKEY(&key),
          mdb_leafnode_type(node));
    }
    total = EVEN(total);
  }
  fprintf(
      stderr,
      "Total: header %d + contents %d + unused %d\n",
      IS_LEAF2(mp) ? PAGEHDRSZ : PAGEBASE + MP_LOWER(mp),
      total,
      SIZELEFT(mp));
}

void mdb_cursor_chk(MDB_cursor* mc) {
  unsigned int i;
  MDB_node* node;
  MDB_page* mp;

  if (!mc->mc_snum || !(mc->mc_flags & C_INITIALIZED))
    return;
  for (i = 0; i < mc->mc_top; i++) {
    mp = mc->mc_pg[i];
    node = NODEPTR(mp, mc->mc_ki[i]);
    if (NODEPGNO(node) != mc->mc_pg[i + 1]->mp_pgno)
      printf("oops!\n");
  }
  if (mc->mc_ki[i] >= NUMKEYS(mc->mc_pg[i]))
    printf("ack!\n");
  if (XCURSOR_INITED(mc)) {
    node = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);
    if (((node->mn_flags & (F_DUPDATA | F_SUBDATA)) == F_DUPDATA) &&
        mc->mc_xcursor->mx_cursor.mc_pg[0] != NODEDATA(node)) {
      printf("blah!\n");
    }
  }
}
#endif

#if (MDB_DEBUG) > 2
/** Count all the pages in each DB and in the freelist
 *  and make sure it matches the actual number of pages
 *  being used.
 *  All named DBs must be open for a correct count.
 */
static void mdb_audit(MDB_txn* txn) {
  MDB_cursor mc;
  MDB_val key, data;
  MDB_ID freecount, count;
  MDB_dbi i;
  int rc;

  freecount = 0;
  mdb_cursor_init(&mc, txn, FREE_DBI, NULL);
  while ((rc = mdb_cursor_get(&mc, &key, &data, MDB_NEXT)) == 0)
    freecount += *(MDB_ID*)data.mv_data;
  mdb_tassert(txn, rc == MDB_NOTFOUND);

  count = 0;
  for (i = 0; i < txn->mt_numdbs; i++) {
    MDB_xcursor mx;
    if (!(txn->mt_dbflags[i] & DB_VALID))
      continue;
    mdb_cursor_init(&mc, txn, i, &mx);
    if (txn->mt_dbs[i].md_root == P_INVALID)
      continue;
    count += txn->mt_dbs[i].md_branch_pages + txn->mt_dbs[i].md_leaf_pages +
        txn->mt_dbs[i].md_overflow_pages;
    if (txn->mt_dbs[i].md_flags & MDB_DUPSORT) {
      rc = mdb_page_search(&mc, NULL, MDB_PS_FIRST);
      for (; rc == MDB_SUCCESS; rc = mdb_cursor_sibling(&mc, 1)) {
        unsigned j;
        MDB_page* mp;
        mp = mc.mc_pg[mc.mc_top];
        for (j = 0; j < NUMKEYS(mp); j++) {
          MDB_node* leaf = NODEPTR(mp, j);
          if (leaf->mn_flags & F_SUBDATA) {
            MDB_db db;
            memcpy(&db, NODEDATA(leaf), sizeof(db));
            count +=
                db.md_branch_pages + db.md_leaf_pages + db.md_overflow_pages;
          }
        }
      }
      mdb_tassert(txn, rc == MDB_NOTFOUND);
    }
  }
  if (freecount + count + NUM_METAS != txn->mt_next_pgno) {
    fprintf(
        stderr,
        "audit: %" Yu " freecount: %" Yu " count: %" Yu " total: %" Yu
        " next_pgno: %" Yu "\n",
        txn->mt_txnid,
        freecount,
        count + NUM_METAS,
        freecount + count + NUM_METAS,
        txn->mt_next_pgno);
  }
}
#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);
}

int mdb_dcmp(MDB_txn* txn, MDB_dbi dbi, const MDB_val* a, const MDB_val* b) {
  MDB_cmp_func* dcmp = txn->mt_dbxs[dbi].md_dcmp;
  if (NEED_CMP_CLONG(dcmp, a->mv_size))
    dcmp = mdb_cmp_clong;
  return dcmp(a, b);
}

/** Allocate memory for a page.
 * Re-use old malloc'd pages first for singletons, otherwise just malloc.
 * Set #MDB_TXN_ERROR on failure.
 */
static MDB_page* mdb_page_malloc(MDB_txn* txn, unsigned num) {
  MDB_env* env = txn->mt_env;
  MDB_page* ret = env->me_dpages;
  size_t psize = env->me_psize, sz = psize, off;
  /* For ! #MDB_NOMEMINIT, psize counts how much to init.
   * For a single page alloc, we init everything after the page header.
   * For multi-page, we init the final page; if the caller needed that
   * many pages they will be filling in at least up to the last page.
   */
  if (num == 1) {
    if (ret) {
      VGMEMP_ALLOC(env, ret, sz);
      VGMEMP_DEFINED(ret, sizeof(ret->mp_next));
      env->me_dpages = ret->mp_next;
      return ret;
    }
    psize -= off = PAGEHDRSZ;
  } else {
    sz *= num;
    off = sz - psize;
  }
  if ((ret = malloc(sz)) != NULL) {
    VGMEMP_ALLOC(env, ret, sz);
    if (!(env->me_flags & MDB_NOMEMINIT)) {
      memset((char*)ret + off, 0, psize);
      ret->mp_pad = 0;
    }
  } else {
    txn->mt_flags |= MDB_TXN_ERROR;
  }
  return ret;
}
/** Free a single page.
 * Saves single pages to a list, for future reuse.
 * (This is not used for multi-page overflow pages.)
 */
static void mdb_page_free(MDB_env* env, MDB_page* mp) {
  mp->mp_next = env->me_dpages;
  VGMEMP_FREE(env, mp);
  env->me_dpages = mp;
}

/** Free a dirty page */
static void mdb_dpage_free(MDB_env* env, MDB_page* dp) {
  if (!IS_OVERFLOW(dp) || dp->mp_pages == 1) {
    mdb_page_free(env, dp);
  } else {
    /* large pages just get freed directly */
    VGMEMP_FREE(env, dp);
    free(dp);
  }
}

/**	Return all dirty pages to dpage list */
static void mdb_dlist_free(MDB_txn* txn) {
  MDB_env* env = txn->mt_env;
  MDB_ID2L dl = txn->mt_u.dirty_list;
  unsigned i, n = dl[0].mid;

  for (i = 1; i <= n; i++) {
    mdb_dpage_free(env, dl[i].mptr);
  }
  dl[0].mid = 0;
}

#ifdef MDB_VL32
static void mdb_page_unref(MDB_txn* txn, MDB_page* mp) {
  pgno_t pgno;
  MDB_ID3L tl = txn->mt_rpages;
  unsigned x, rem;
  if (mp->mp_flags & (P_SUBP | P_DIRTY))
    return;
  rem = mp->mp_pgno & (MDB_RPAGE_CHUNK - 1);
  pgno = mp->mp_pgno ^ rem;
  x = mdb_mid3l_search(tl, pgno);
  if (x != tl[0].mid && tl[x + 1].mid == mp->mp_pgno)
    x++;
  if (tl[x].mref)
    tl[x].mref--;
}
#define MDB_PAGE_UNREF(txn, mp) mdb_page_unref(txn, mp)

static void mdb_cursor_unref(MDB_cursor* mc) {
  int i;
  if (mc->mc_txn->mt_rpages[0].mid) {
    if (!mc->mc_snum || !mc->mc_pg[0] || IS_SUBP(mc->mc_pg[0]))
      return;
    for (i = 0; i < mc->mc_snum; i++)
      mdb_page_unref(mc->mc_txn, mc->mc_pg[i]);
    if (mc->mc_ovpg) {
      mdb_page_unref(mc->mc_txn, mc->mc_ovpg);
      mc->mc_ovpg = 0;
    }
  }
  mc->mc_snum = mc->mc_top = 0;
  mc->mc_pg[0] = NULL;
  mc->mc_flags &= ~C_INITIALIZED;
}
#define MDB_CURSOR_UNREF(mc, force)                                     \
  (((force) || ((mc)->mc_flags & C_INITIALIZED)) ? mdb_cursor_unref(mc) \
                                                 : (void)0)

#else
#define MDB_PAGE_UNREF(txn, mp)
#define MDB_CURSOR_UNREF(mc, force) ((void)0)
#endif /* MDB_VL32 */

/** Loosen or free a single page.
 * Saves single pages to a list for future reuse
 * in this same txn. It has been pulled from the freeDB
 * and already resides on the dirty list, but has been
 * deleted. Use these pages first before pulling again
 * from the freeDB.
 *
 * If the page wasn't dirtied in this txn, just add it
 * to this txn's free list.
 */
static int mdb_page_loose(MDB_cursor* mc, MDB_page* mp) {
  int loose = 0;
  pgno_t pgno = mp->mp_pgno;
  MDB_txn* txn = mc->mc_txn;

  if ((mp->mp_flags & P_DIRTY) && mc->mc_dbi != FREE_DBI) {
    if (txn->mt_parent) {
      MDB_ID2* dl = txn->mt_u.dirty_list;
      /* If txn has a parent, make sure the page is in our
       * dirty list.
       */
      if (dl[0].mid) {
        unsigned x = mdb_mid2l_search(dl, pgno);
        if (x <= dl[0].mid && dl[x].mid == pgno) {
          if (mp != dl[x].mptr) { /* bad cursor? */
            mc->mc_flags &= ~(C_INITIALIZED | C_EOF);
            txn->mt_flags |= MDB_TXN_ERROR;
            return MDB_PROBLEM;
          }
          /* ok, it's ours */
          loose = 1;
        }
      }
    } else {
      /* no parent txn, so it's just ours */
      loose = 1;
    }
  }
  if (loose) {
    DPRINTF(("loosen db %d page %" Yu, DDBI(mc), mp->mp_pgno));
    NEXT_LOOSE_PAGE(mp) = txn->mt_loose_pgs;
    txn->mt_loose_pgs = mp;
    txn->mt_loose_count++;
    mp->mp_flags |= P_LOOSE;
  } else {
    int rc = mdb_midl_append(&txn->mt_free_pgs, pgno);
    if (rc)
      return rc;
  }

  return MDB_SUCCESS;
}

/** Set or clear P_KEEP in dirty, non-overflow, non-sub pages watched by txn.
 * @param[in] mc A cursor handle for the current operation.
 * @param[in] pflags Flags of the pages to update:
 * P_DIRTY to set P_KEEP, P_DIRTY|P_KEEP to clear it.
 * @param[in] all No shortcuts. Needed except after a full #mdb_page_flush().
 * @return 0 on success, non-zero on failure.
 */
static int mdb_pages_xkeep(MDB_cursor* mc, unsigned pflags, int all) {
  enum { Mask = P_SUBP | P_DIRTY | P_LOOSE | P_KEEP };
  MDB_txn* txn = mc->mc_txn;
  MDB_cursor *m3, *m0 = mc;
  MDB_xcursor* mx;
  MDB_page *dp, *mp;
  MDB_node* leaf;
  unsigned i, j;
  int rc = MDB_SUCCESS, level;

  /* Mark pages seen by cursors: First m0, then tracked cursors */
  for (i = txn->mt_numdbs;;) {
    if (mc->mc_flags & C_INITIALIZED) {
      for (m3 = mc;; m3 = &mx->mx_cursor) {
        mp = NULL;
        for (j = 0; j < m3->mc_snum; j++) {
          mp = m3->mc_pg[j];
          if ((mp->mp_flags & Mask) == pflags)
            mp->mp_flags ^= P_KEEP;
        }
        mx = m3->mc_xcursor;
        /* Proceed to mx if it is at a sub-database */
        if (!(mx && (mx->mx_cursor.mc_flags & C_INITIALIZED)))
          break;
        if (!(mp && (mp->mp_flags & P_LEAF)))
          break;
        leaf = NODEPTR(mp, m3->mc_ki[j - 1]);
        if (!(leaf->mn_flags & F_SUBDATA))
          break;
      }
    }
    mc = mc->mc_next;
    for (; !mc || mc == m0; mc = txn->mt_cursors[--i])
      if (i == 0)
        goto mark_done;
  }

mark_done:
  if (all) {
    /* Mark dirty root pages */
    for (i = 0; i < txn->mt_numdbs; i++) {
      if (txn->mt_dbflags[i] & DB_DIRTY) {
        pgno_t pgno = txn->mt_dbs[i].md_root;
        if (pgno == P_INVALID)
          continue;
        if ((rc = mdb_page_get(m0, pgno, &dp, &level)) != MDB_SUCCESS)
          break;
        if ((dp->mp_flags & Mask) == pflags && level <= 1)
          dp->mp_flags ^= P_KEEP;
      }
    }
  }

  return rc;
}

static int mdb_page_flush(MDB_txn* txn, int keep);

/**	Spill pages from the dirty list back to disk.
 * This is intended to prevent running into #MDB_TXN_FULL situations,
 * but note that they may still occur in a few cases:
 *	1) our estimate of the txn size could be too small. Currently this
 *	 seems unlikely, except with a large number of #MDB_MULTIPLE items.
 *	2) child txns may run out of space if their parents dirtied a
 *	 lot of pages and never spilled them. TODO: we probably should do
 *	 a preemptive spill during #mdb_txn_begin() of a child txn, if
 *	 the parent's dirty_room is below a given threshold.
 *
 * Otherwise, if not using nested txns, it is expected that apps will
 * not run into #MDB_TXN_FULL any more. The pages are flushed to disk
 * the same way as for a txn commit, e.g. their P_DIRTY flag is cleared.
 * If the txn never references them again, they can be left alone.
 * If the txn only reads them, they can be used without any fuss.
 * If the txn writes them again, they can be dirtied immediately without
 * going thru all of the work of #mdb_page_touch(). Such references are
 * handled by #mdb_page_unspill().
 *
 * Also note, we never spill DB root pages, nor pages of active cursors,
 * because we'll need these back again soon anyway. And in nested txns,
 * we can't spill a page in a child txn if it was already spilled in a
 * parent txn. That would alter the parent txns' data even though
 * the child hasn't committed yet, and we'd have no way to undo it if
 * the child aborted.
 *
 * @param[in] m0 cursor A cursor handle identifying the transaction and
 *	database for which we are checking space.
 * @param[in] key For a put operation, the key being stored.
 * @param[in] data For a put operation, the data being stored.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_spill(MDB_cursor* m0, MDB_val* key, MDB_val* data) {
  MDB_txn* txn = m0->mc_txn;
  MDB_page* dp;
  MDB_ID2L dl = txn->mt_u.dirty_list;
  unsigned int i, j, need;
  int rc;

  if (m0->mc_flags & C_SUB)
    return MDB_SUCCESS;

  /* Estimate how much space this op will take */
  i = m0->mc_db->md_depth;
  /* Named DBs also dirty the main DB */
  if (m0->mc_dbi >= CORE_DBS)
    i += txn->mt_dbs[MAIN_DBI].md_depth;
  /* For puts, roughly factor in the key+data size */
  if (key)
    i += (LEAFSIZE(key, data) + txn->mt_env->me_psize) / txn->mt_env->me_psize;
  i += i; /* double it for good measure */
  need = i;

  if (txn->mt_dirty_room > i)
    return MDB_SUCCESS;

  if (!txn->mt_spill_pgs) {
    txn->mt_spill_pgs = mdb_midl_alloc(MDB_IDL_UM_MAX);
    if (!txn->mt_spill_pgs)
      return ENOMEM;
  } else {
    /* purge deleted slots */
    MDB_IDL sl = txn->mt_spill_pgs;
    unsigned int num = sl[0];
    j = 0;
    for (i = 1; i <= num; i++) {
      if (!(sl[i] & 1))
        sl[++j] = sl[i];
    }
    sl[0] = j;
  }

  /* Preserve pages which may soon be dirtied again */
  if ((rc = mdb_pages_xkeep(m0, P_DIRTY, 1)) != MDB_SUCCESS)
    goto done;

  /* Less aggressive spill - we originally spilled the entire dirty list,
   * with a few exceptions for cursor pages and DB root pages. But this
   * turns out to be a lot of wasted effort because in a large txn many
   * of those pages will need to be used again. So now we spill only 1/8th
   * of the dirty pages. Testing revealed this to be a good tradeoff,
   * better than 1/2, 1/4, or 1/10.
   */
  if (need < MDB_IDL_UM_MAX / 8)
    need = MDB_IDL_UM_MAX / 8;

  /* Save the page IDs of all the pages we're flushing */
  /* flush from the tail forward, this saves a lot of shifting later on. */
  for (i = dl[0].mid; i && need; i--) {
    MDB_ID pn = dl[i].mid << 1;
    dp = dl[i].mptr;
    if (dp->mp_flags & (P_LOOSE | P_KEEP))
      continue;
    /* Can't spill twice, make sure it's not already in a parent's
     * spill list.
     */
    if (txn->mt_parent) {
      MDB_txn* tx2;
      for (tx2 = txn->mt_parent; tx2; tx2 = tx2->mt_parent) {
        if (tx2->mt_spill_pgs) {
          j = mdb_midl_search(tx2->mt_spill_pgs, pn);
          if (j <= tx2->mt_spill_pgs[0] && tx2->mt_spill_pgs[j] == pn) {
            dp->mp_flags |= P_KEEP;
            break;
          }
        }
      }
      if (tx2)
        continue;
    }
    if ((rc = mdb_midl_append(&txn->mt_spill_pgs, pn)))
      goto done;
    need--;
  }
  mdb_midl_sort(txn->mt_spill_pgs);

  /* Flush the spilled part of dirty list */
  if ((rc = mdb_page_flush(txn, i)) != MDB_SUCCESS)
    goto done;

  /* Reset any dirty pages we kept that page_flush didn't see */
  rc = mdb_pages_xkeep(m0, P_DIRTY | P_KEEP, i);

done:
  txn->mt_flags |= rc ? MDB_TXN_ERROR : MDB_TXN_SPILLS;
  return rc;
}

/** Find oldest txnid still referenced. Expects txn->mt_txnid > 0. */
static txnid_t mdb_find_oldest(MDB_txn* txn) {
  int i;
  txnid_t mr, oldest = txn->mt_txnid - 1;
  if (txn->mt_env->me_txns) {
    MDB_reader* r = txn->mt_env->me_txns->mti_readers;
    for (i = txn->mt_env->me_txns->mti_numreaders; --i >= 0;) {
      if (r[i].mr_pid) {
        mr = r[i].mr_txnid;
        if (oldest > mr)
          oldest = mr;
      }
    }
  }
  return oldest;
}

/** Add a page to the txn's dirty list */
static void mdb_page_dirty(MDB_txn* txn, MDB_page* mp) {
  MDB_ID2 mid;
  int rc, (*insert)(MDB_ID2L, MDB_ID2*);
#ifdef _WIN32 /* With Windows we always write dirty pages with WriteFile, \
               * so we always want them ordered */
  insert = mdb_mid2l_insert;
#else /* but otherwise with writemaps, we just use msync, we \
       * don't need the ordering and just append */
  if (txn->mt_flags & MDB_TXN_WRITEMAP)
    insert = mdb_mid2l_append;
  else
    insert = mdb_mid2l_insert;
#endif
  mid.mid = mp->mp_pgno;
  mid.mptr = mp;
  rc = insert(txn->mt_u.dirty_list, &mid);
  mdb_tassert(txn, rc == 0);
  txn->mt_dirty_room--;
}

/** Allocate page numbers and memory for writing.  Maintain me_pglast,
 * me_pghead and mt_next_pgno.  Set #MDB_TXN_ERROR on failure.
 *
 * If there are free pages available from older transactions, they
 * are re-used first. Otherwise allocate a new page at mt_next_pgno.
 * Do not modify the freedB, just merge freeDB records into me_pghead[]
 * and move me_pglast to say which records were consumed.  Only this
 * function can create me_pghead and move me_pglast/mt_next_pgno.
 * When #MDB_DEVEL & 2, it is not affected by #mdb_freelist_save(): it
 * then uses the transaction's original snapshot of the freeDB.
 * @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.
 * @param[out] mp Address of the allocated page(s). Requests for multiple pages
 *  will always be satisfied by a single contiguous chunk of memory.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_alloc(MDB_cursor* mc, int num, MDB_page** mp) {
#ifdef MDB_PARANOID /* Seems like we can ignore this now */
  /* Get at most <Max_retries> more freeDB records once me_pghead
   * has enough pages.  If not enough, use new pages from the map.
   * If <Paranoid> and mc is updating the freeDB, only get new
   * records if me_pghead is empty. Then the freelist cannot play
   * catch-up with itself by growing while trying to save it.
   */
  enum { Paranoid = 1, Max_retries = 500 };
#else
  enum { Paranoid = 0, Max_retries = INT_MAX /*infinite*/ };
#endif
  int rc, retry = num * 60;
  MDB_txn* txn = mc->mc_txn;
  MDB_env* env = txn->mt_env;
  pgno_t pgno, *mop = env->me_pghead;
  unsigned i, j, mop_len = mop ? mop[0] : 0, n2 = num - 1;
  MDB_page* np;
  txnid_t oldest = 0, last;
  MDB_cursor_op op;
  MDB_cursor m2;
  int found_old = 0;

  /* If there are any loose pages, just use them */
  if (num == 1 && txn->mt_loose_pgs) {
    np = txn->mt_loose_pgs;
    txn->mt_loose_pgs = NEXT_LOOSE_PAGE(np);
    txn->mt_loose_count--;
    DPRINTF(("db %d use loose page %" Yu, DDBI(mc), np->mp_pgno));
    *mp = np;
    return MDB_SUCCESS;
  }

  *mp = NULL;

  /* If our dirty list is already full, we can't do anything */
  if (txn->mt_dirty_room == 0) {
    rc = MDB_TXN_FULL;
    goto fail;
  }

  for (op = MDB_FIRST;; op = MDB_NEXT) {
    MDB_val key, data;
    MDB_node* leaf;
    pgno_t* idl;

    /* Seek a big enough contiguous page range. Prefer
     * pages at the tail, just truncating the list.
     */
    if (mop_len > n2) {
      i = mop_len;
      do {
        pgno = mop[i];
        if (mop[i - n2] == pgno + n2)
          goto search_done;
      } while (--i > n2);
      if (--retry < 0)
        break;
    }

    if (op == MDB_FIRST) { /* 1st iteration */
      /* Prepare to fetch more and coalesce */
      last = env->me_pglast;
      oldest = env->me_pgoldest;
      mdb_cursor_init(&m2, txn, FREE_DBI, NULL);
#if (MDB_DEVEL) & 2 /* "& 2" so MDB_DEVEL=1 won't hide bugs breaking freeDB */
      /* Use original snapshot. TODO: Should need less care in code
       * which modifies the database. Maybe we can delete some code?
       */
      m2.mc_flags |= C_ORIG_RDONLY;
      m2.mc_db = &env->me_metas[(txn->mt_txnid - 1) & 1]->mm_dbs[FREE_DBI];
      m2.mc_dbflag = (unsigned char*)""; /* probably unnecessary */
#endif
      if (last) {
        op = MDB_SET_RANGE;
        key.mv_data = &last; /* will look up last+1 */
        key.mv_size = sizeof(last);
      }
      if (Paranoid && mc->mc_dbi == FREE_DBI)
        retry = -1;
    }
    if (Paranoid && retry < 0 && mop_len)
      break;

    last++;
    /* Do not fetch more if the record will be too recent */
    if (oldest <= last) {
      if (!found_old) {
        oldest = mdb_find_oldest(txn);
        env->me_pgoldest = oldest;
        found_old = 1;
      }
      if (oldest <= last)
        break;
    }
    rc = mdb_cursor_get(&m2, &key, NULL, op);
    if (rc) {
      if (rc == MDB_NOTFOUND)
        break;
      goto fail;
    }
    last = *(txnid_t*)key.mv_data;
    if (oldest <= last) {
      if (!found_old) {
        oldest = mdb_find_oldest(txn);
        env->me_pgoldest = oldest;
        found_old = 1;
      }
      if (oldest <= last)
        break;
    }
    np = m2.mc_pg[m2.mc_top];
    leaf = NODEPTR(np, m2.mc_ki[m2.mc_top]);
    if ((rc = mdb_node_read(&m2, leaf, &data)) != MDB_SUCCESS)
      goto fail;

    idl = (MDB_ID*)data.mv_data;
    i = idl[0];
    if (!mop) {
      if (!(env->me_pghead = mop = mdb_midl_alloc(i))) {
        rc = ENOMEM;
        goto fail;
      }
    } else {
      if ((rc = mdb_midl_need(&env->me_pghead, i)) != 0)
        goto fail;
      mop = env->me_pghead;
    }
    env->me_pglast = last;
#if (MDB_DEBUG) > 1
    DPRINTF(
        ("IDL read txn %" Yu " root %" Yu " num %u",
         last,
         txn->mt_dbs[FREE_DBI].md_root,
         i));
    for (j = i; j; j--)
      DPRINTF(("IDL %" Yu, idl[j]));
#endif
    /* Merge in descending sorted order */
    mdb_midl_xmerge(mop, idl);
    mop_len = mop[0];
  }

  /* Use new pages from the map when nothing suitable in the freeDB */
  i = 0;
  pgno = txn->mt_next_pgno;
  if (pgno + num >= env->me_maxpg) {
    DPUTS("DB size maxed out");
    rc = MDB_MAP_FULL;
    goto fail;
  }
#if defined(_WIN32) && !defined(MDB_VL32)
  if (!(env->me_flags & MDB_RDONLY)) {
    void* p;
    p = (MDB_page*)(env->me_map + env->me_psize * pgno);
    p = VirtualAlloc(
        p,
        env->me_psize * num,
        MEM_COMMIT,
        (env->me_flags & MDB_WRITEMAP) ? PAGE_READWRITE : PAGE_READONLY);
    if (!p) {
      DPUTS("VirtualAlloc failed");
      rc = ErrCode();
      goto fail;
    }
  }
#endif

search_done:
  if (env->me_flags & MDB_WRITEMAP) {
    np = (MDB_page*)(env->me_map + env->me_psize * pgno);
  } else {
    if (!(np = mdb_page_malloc(txn, num))) {
      rc = ENOMEM;
      goto fail;
    }
  }
  if (i) {
    mop[0] = mop_len -= num;
    /* Move any stragglers down */
    for (j = i - num; j < mop_len;)
      mop[++j] = mop[++i];
  } else {
    txn->mt_next_pgno = pgno + num;
  }
  np->mp_pgno = pgno;
  mdb_page_dirty(txn, np);
  *mp = np;

  return MDB_SUCCESS;

fail:
  txn->mt_flags |= MDB_TXN_ERROR;
  return rc;
}

/** Copy the used portions of a non-overflow page.
 * @param[in] dst page to copy into
 * @param[in] src page to copy from
 * @param[in] psize size of a page
 */
static void mdb_page_copy(MDB_page* dst, MDB_page* src, unsigned int psize) {
  enum { Align = sizeof(pgno_t) };
  indx_t upper = src->mp_upper, lower = src->mp_lower, unused = upper - lower;

  /* If page isn't full, just copy the used portion. Adjust
   * alignment so memcpy may copy words instead of bytes.
   */
  if ((unused &= -Align) && !IS_LEAF2(src)) {
    upper = (upper + PAGEBASE) & -Align;
    memcpy(dst, src, (lower + PAGEBASE + (Align - 1)) & -Align);
    memcpy(
        (pgno_t*)((char*)dst + upper),
        (pgno_t*)((char*)src + upper),
        psize - upper);
  } else {
    memcpy(dst, src, psize - unused);
  }
}

/** Pull a page off the txn's spill list, if present.
 * If a page being referenced was spilled to disk in this txn, bring
 * it back and make it dirty/writable again.
 * @param[in] txn the transaction handle.
 * @param[in] mp the page being referenced. It must not be dirty.
 * @param[out] ret the writable page, if any. ret is unchanged if
 * mp wasn't spilled.
 */
static int mdb_page_unspill(MDB_txn* txn, MDB_page* mp, MDB_page** ret) {
  MDB_env* env = txn->mt_env;
  const MDB_txn* tx2;
  unsigned x;
  pgno_t pgno = mp->mp_pgno, pn = pgno << 1;

  for (tx2 = txn; tx2; tx2 = tx2->mt_parent) {
    if (!tx2->mt_spill_pgs)
      continue;
    x = mdb_midl_search(tx2->mt_spill_pgs, pn);
    if (x <= tx2->mt_spill_pgs[0] && tx2->mt_spill_pgs[x] == pn) {
      MDB_page* np;
      int num;
      if (txn->mt_dirty_room == 0)
        return MDB_TXN_FULL;
      if (IS_OVERFLOW(mp))
        num = mp->mp_pages;
      else
        num = 1;
      if (env->me_flags & MDB_WRITEMAP) {
        np = mp;
      } else {
        np = mdb_page_malloc(txn, num);
        if (!np)
          return ENOMEM;
        if (num > 1)
          memcpy(np, mp, num * env->me_psize);
        else
          mdb_page_copy(np, mp, env->me_psize);
      }
      if (tx2 == txn) {
        /* If in current txn, this page is no longer spilled.
         * If it happens to be the last page, truncate the spill list.
         * Otherwise mark it as deleted by setting the LSB.
         */
        if (x == txn->mt_spill_pgs[0])
          txn->mt_spill_pgs[0]--;
        else
          txn->mt_spill_pgs[x] |= 1;
      } /* otherwise, if belonging to a parent txn, the
         * page remains spilled until child commits
         */

      mdb_page_dirty(txn, np);
      np->mp_flags |= P_DIRTY;
      *ret = np;
      break;
    }
  }
  return MDB_SUCCESS;
}

/** Touch a page: make it dirty and re-insert into tree with updated pgno.
 * Set #MDB_TXN_ERROR on failure.
 * @param[in] mc cursor pointing to the page to be touched
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_touch(MDB_cursor* mc) {
  MDB_page *mp = mc->mc_pg[mc->mc_top], *np;
  MDB_txn* txn = mc->mc_txn;
  MDB_cursor *m2, *m3;
  pgno_t pgno;
  int rc;

  if (!F_ISSET(MP_FLAGS(mp), P_DIRTY)) {
    if (txn->mt_flags & MDB_TXN_SPILLS) {
      np = NULL;
      rc = mdb_page_unspill(txn, mp, &np);
      if (rc)
        goto fail;
      if (np)
        goto done;
    }
    if ((rc = mdb_midl_need(&txn->mt_free_pgs, 1)) ||
        (rc = mdb_page_alloc(mc, 1, &np)))
      goto fail;
    pgno = np->mp_pgno;
    DPRINTF(
        ("touched db %d page %" Yu " -> %" Yu, DDBI(mc), mp->mp_pgno, pgno));
    mdb_cassert(mc, mp->mp_pgno != pgno);
    mdb_midl_xappend(txn->mt_free_pgs, mp->mp_pgno);
    /* Update the parent page, if any, to point to the new page */
    if (mc->mc_top) {
      MDB_page* parent = mc->mc_pg[mc->mc_top - 1];
      MDB_node* node = NODEPTR(parent, mc->mc_ki[mc->mc_top - 1]);
      SETPGNO(node, pgno);
    } else {
      mc->mc_db->md_root = pgno;
    }
  } else if (txn->mt_parent && !IS_SUBP(mp)) {
    MDB_ID2 mid, *dl = txn->mt_u.dirty_list;
    pgno = mp->mp_pgno;
    /* If txn has a parent, make sure the page is in our
     * dirty list.
     */
    if (dl[0].mid) {
      unsigned x = mdb_mid2l_search(dl, pgno);
      if (x <= dl[0].mid && dl[x].mid == pgno) {
        if (mp != dl[x].mptr) { /* bad cursor? */
          mc->mc_flags &= ~(C_INITIALIZED | C_EOF);
          txn->mt_flags |= MDB_TXN_ERROR;
          return MDB_PROBLEM;
        }
        return 0;
      }
    }
    mdb_cassert(mc, dl[0].mid < MDB_IDL_UM_MAX);
    /* No - copy it */
    np = mdb_page_malloc(txn, 1);
    if (!np)
      return ENOMEM;
    mid.mid = pgno;
    mid.mptr = np;
    rc = mdb_mid2l_insert(dl, &mid);
    mdb_cassert(mc, rc == 0);
  } else {
    return 0;
  }

  mdb_page_copy(np, mp, txn->mt_env->me_psize);
  np->mp_pgno = pgno;
  np->mp_flags |= P_DIRTY;

done:
  /* Adjust cursors pointing to mp */
  mc->mc_pg[mc->mc_top] = np;
  m2 = txn->mt_cursors[mc->mc_dbi];
  if (mc->mc_flags & C_SUB) {
    for (; m2; m2 = m2->mc_next) {
      m3 = &m2->mc_xcursor->mx_cursor;
      if (m3->mc_snum < mc->mc_snum)
        continue;
      if (m3->mc_pg[mc->mc_top] == mp)
        m3->mc_pg[mc->mc_top] = np;
    }
  } else {
    for (; m2; m2 = m2->mc_next) {
      if (m2->mc_snum < mc->mc_snum)
        continue;
      if (m2 == mc)
        continue;
      if (m2->mc_pg[mc->mc_top] == mp) {
        m2->mc_pg[mc->mc_top] = np;
        if (IS_LEAF(np))
          XCURSOR_REFRESH(m2, mc->mc_top, np);
      }
    }
  }
  MDB_PAGE_UNREF(mc->mc_txn, mp);
  return 0;

fail:
  txn->mt_flags |= MDB_TXN_ERROR;
  return rc;
}

int mdb_env_sync0(MDB_env* env, int force, pgno_t numpgs) {
  int rc = 0;
  if (env->me_flags & MDB_RDONLY)
    return EACCES;
  if (force
#ifndef _WIN32 /* Sync is normally achieved in Windows by doing WRITE_THROUGH \
                  writes */
      || !(env->me_flags & MDB_NOSYNC)
#endif
  ) {
    if (env->me_flags & MDB_WRITEMAP) {
      int flags =
          ((env->me_flags & MDB_MAPASYNC) && !force) ? MS_ASYNC : MS_SYNC;
      if (MDB_MSYNC(env->me_map, env->me_psize * numpgs, flags))
        rc = ErrCode();
#if defined(_WIN32) || defined(__APPLE__)
      else if (flags == MS_SYNC && MDB_FDATASYNC(env->me_fd))
        rc = ErrCode();
#endif
    } else {
#ifdef BROKEN_FDATASYNC
      if (env->me_flags & MDB_FSYNCONLY) {
        if (fsync(env->me_fd))
          rc = ErrCode();
      } else
#endif
          if (MDB_FDATASYNC(env->me_fd))
        rc = ErrCode();
    }
  }
  return rc;
}

int mdb_env_sync(MDB_env* env, int force) {
  MDB_meta* m = mdb_env_pick_meta(env);
  return mdb_env_sync0(env, force, m->mm_last_pg + 1);
}

/** Back up parent txn's cursors, then grab the originals for tracking */
static int mdb_cursor_shadow(MDB_txn* src, MDB_txn* dst) {
  MDB_cursor *mc, *bk;
  MDB_xcursor* mx;
  size_t size;
  int i;

  for (i = src->mt_numdbs; --i >= 0;) {
    if ((mc = src->mt_cursors[i]) != NULL) {
      size = sizeof(MDB_cursor);
      if (mc->mc_xcursor)
        size += sizeof(MDB_xcursor);
      for (; mc; mc = bk->mc_next) {
        bk = malloc(size);
        if (!bk)
          return ENOMEM;
        *bk = *mc;
        mc->mc_backup = bk;
        mc->mc_db = &dst->mt_dbs[i];
        /* Kill pointers into src to reduce abuse: The
         * user may not use mc until dst ends. But we need a valid
         * txn pointer here for cursor fixups to keep working.
         */
        mc->mc_txn = dst;
        mc->mc_dbflag = &dst->mt_dbflags[i];
        if ((mx = mc->mc_xcursor) != NULL) {
          *(MDB_xcursor*)(bk + 1) = *mx;
          mx->mx_cursor.mc_txn = dst;
        }
        mc->mc_next = dst->mt_cursors[i];
        dst->mt_cursors[i] = mc;
      }
    }
  }
  return MDB_SUCCESS;
}

/** Close this write txn's cursors, give parent txn's cursors back to parent.
 * @param[in] txn the transaction handle.
 * @param[in] merge true to keep changes to parent cursors, false to revert.
 * @return 0 on success, non-zero on failure.
 */
static void mdb_cursors_close(MDB_txn* txn, unsigned merge) {
  MDB_cursor **cursors = txn->mt_cursors, *mc, *next, *bk;
  MDB_xcursor* mx;
  int i;

  for (i = txn->mt_numdbs; --i >= 0;) {
    for (mc = cursors[i]; mc; mc = next) {
      next = mc->mc_next;
      if ((bk = mc->mc_backup) != NULL) {
        if (merge) {
          /* Commit changes to parent txn */
          mc->mc_next = bk->mc_next;
          mc->mc_backup = bk->mc_backup;
          mc->mc_txn = bk->mc_txn;
          mc->mc_db = bk->mc_db;
          mc->mc_dbflag = bk->mc_dbflag;
          if ((mx = mc->mc_xcursor) != NULL)
            mx->mx_cursor.mc_txn = bk->mc_txn;
        } else {
          /* Abort nested txn */
          *mc = *bk;
          if ((mx = mc->mc_xcursor) != NULL)
            *mx = *(MDB_xcursor*)(bk + 1);
        }
        mc = bk;
      }
      /* Only malloced cursors are permanently tracked. */
      free(mc);
    }
    cursors[i] = NULL;
  }
}

#if !(MDB_PIDLOCK) /* Currently the same as defined(_WIN32) */
enum Pidlock_op { Pidset, Pidcheck };
#else
enum Pidlock_op { Pidset = F_SETLK, Pidcheck = F_GETLK };
#endif

/** Set or check a pid lock. Set returns 0 on success.
 * Check returns 0 if the process is certainly dead, nonzero if it may
 * be alive (the lock exists or an error happened so we do not know).
 *
 * On Windows Pidset is a no-op, we merely check for the existence
 * of the process with the given pid. On POSIX we use a single byte
 * lock on the lockfile, set at an offset equal to the pid.
 */
static int mdb_reader_pid(MDB_env* env, enum Pidlock_op op, MDB_PID_T pid) {
#if !(MDB_PIDLOCK) /* Currently the same as defined(_WIN32) */
  int ret = 0;
  HANDLE h;
  if (op == Pidcheck) {
    h = OpenProcess(env->me_pidquery, FALSE, pid);
    /* No documented "no such process" code, but other program use this: */
    if (!h)
      return ErrCode() != ERROR_INVALID_PARAMETER;
    /* A process exists until all handles to it close. Has it exited? */
    ret = WaitForSingleObject(h, 0) != 0;
    CloseHandle(h);
  }
  return ret;
#else
  for (;;) {
    int rc;
    struct flock lock_info;
    memset(&lock_info, 0, sizeof(lock_info));
    lock_info.l_type = F_WRLCK;
    lock_info.l_whence = SEEK_SET;
    lock_info.l_start = pid;
    lock_info.l_len = 1;
    if ((rc = fcntl(env->me_lfd, op, &lock_info)) == 0) {
      if (op == F_GETLK && lock_info.l_type != F_UNLCK)
        rc = -1;
    } else if ((rc = ErrCode()) == EINTR) {
      continue;
    }
    return rc;
  }
#endif
}

/** 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.
 */
static int mdb_txn_renew0(MDB_txn* txn) {
  MDB_env* env = txn->mt_env;
  MDB_txninfo* ti = env->me_txns;
  MDB_meta* meta;
  unsigned int i, nr, flags = txn->mt_flags;
  uint16_t x;
  int rc, new_notls = 0;

  if ((flags &= MDB_TXN_RDONLY) != 0) {
    if (!ti) {
      meta = mdb_env_pick_meta(env);
      txn->mt_txnid = meta->mm_txnid;
      txn->mt_u.reader = NULL;
    } else {
      MDB_reader* r = (env->me_flags & MDB_NOTLS)
          ? txn->mt_u.reader
          : pthread_getspecific(env->me_txkey);
      if (r) {
        if (r->mr_pid != env->me_pid || r->mr_txnid != (txnid_t)-1)
          return MDB_BAD_RSLOT;
      } else {
        MDB_PID_T pid = env->me_pid;
        MDB_THR_T tid = pthread_self();
        mdb_mutexref_t rmutex = env->me_rmutex;

        if (!env->me_live_reader) {
          rc = mdb_reader_pid(env, Pidset, pid);
          if (rc)
            return rc;
          env->me_live_reader = 1;
        }

        if (LOCK_MUTEX(rc, env, rmutex))
          return rc;
        nr = ti->mti_numreaders;
        for (i = 0; i < nr; i++)
          if (ti->mti_readers[i].mr_pid == 0)
            break;
        if (i == env->me_maxreaders) {
          UNLOCK_MUTEX(rmutex);
          return MDB_READERS_FULL;
        }
        r = &ti->mti_readers[i];
        /* Claim the reader slot, carefully since other code
         * uses the reader table un-mutexed: First reset the
         * slot, next publish it in mti_numreaders.  After
         * that, it is safe for mdb_env_close() to touch it.
         * When it will be closed, we can finally claim it.
         */
        r->mr_pid = 0;
        r->mr_txnid = (txnid_t)-1;
        r->mr_tid = tid;
        if (i == nr)
          ti->mti_numreaders = ++nr;
        env->me_close_readers = nr;
        r->mr_pid = pid;
        UNLOCK_MUTEX(rmutex);

        new_notls = (env->me_flags & MDB_NOTLS);
        if (!new_notls && (rc = pthread_setspecific(env->me_txkey, r))) {
          r->mr_pid = 0;
          return rc;
        }
      }
      do /* LY: Retry on a race, ITS#7970. */
        r->mr_txnid = ti->mti_txnid;
      while (r->mr_txnid != ti->mti_txnid);
      if (!r->mr_txnid && (env->me_flags & MDB_RDONLY)) {
        meta = mdb_env_pick_meta(env);
        r->mr_txnid = meta->mm_txnid;
      } else {
        meta = env->me_metas[r->mr_txnid & 1];
      }
      txn->mt_txnid = r->mr_txnid;
      txn->mt_u.reader = r;
    }

  } else {
    /* Not yet touching txn == env->me_txn0, it may be active */
    if (ti) {
      if (LOCK_MUTEX(rc, env, env->me_wmutex))
        return rc;
      txn->mt_txnid = ti->mti_txnid;
      meta = env->me_metas[txn->mt_txnid & 1];
    } else {
      meta = mdb_env_pick_meta(env);
      txn->mt_txnid = meta->mm_txnid;
    }
    txn->mt_txnid++;
#if MDB_DEBUG
    if (txn->mt_txnid == mdb_debug_start)
      mdb_debug = MDB_DBG_INFO;
#endif
    txn->mt_child = NULL;
    txn->mt_loose_pgs = NULL;
    txn->mt_loose_count = 0;
    txn->mt_dirty_room = MDB_IDL_UM_MAX;
    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_spill_pgs = NULL;
    env->me_txn = txn;
    memcpy(
        txn->mt_dbiseqs,
        env->me_dbiseqs,
        env->me_maxdbs * sizeof(unsigned int));
  }

  /* Copy the DB info and flags */
  memcpy(txn->mt_dbs, meta->mm_dbs, CORE_DBS * sizeof(MDB_db));

  /* Moved to here to avoid a data race in read TXNs */
  txn->mt_next_pgno = meta->mm_last_pg + 1;
#ifdef MDB_VL32
  txn->mt_last_pgno = txn->mt_next_pgno - 1;
#endif

  txn->mt_flags = flags;

  /* Setup db info */
  txn->mt_numdbs = env->me_numdbs;
  for (i = CORE_DBS; i < txn->mt_numdbs; i++) {
    x = env->me_dbflags[i];
    txn->mt_dbs[i].md_flags = x & PERSISTENT_FLAGS;
    txn->mt_dbflags[i] =
        (x & MDB_VALID) ? DB_VALID | DB_USRVALID | DB_STALE : 0;
  }
  txn->mt_dbflags[MAIN_DBI] = DB_VALID | DB_USRVALID;
  txn->mt_dbflags[FREE_DBI] = DB_VALID;

  if (env->me_flags & MDB_FATAL_ERROR) {
    DPUTS("environment had fatal error, must shutdown!");
    rc = MDB_PANIC;
  } else if (env->me_maxpg < txn->mt_next_pgno) {
    rc = MDB_MAP_RESIZED;
  } else {
    return MDB_SUCCESS;
  }
  mdb_txn_end(txn, new_notls /*0 or MDB_END_SLOT*/ | MDB_END_FAIL_BEGIN);
  return rc;
}

int mdb_txn_renew(MDB_txn* txn) {
  int rc;

  if (!txn || !F_ISSET(txn->mt_flags, MDB_TXN_RDONLY | MDB_TXN_FINISHED))
    return EINVAL;

  rc = mdb_txn_renew0(txn);
  if (rc == MDB_SUCCESS) {
    DPRINTF(
        ("renew txn %" Yu "%c %p on mdbenv %p, root page %" Yu,
         txn->mt_txnid,
         (txn->mt_flags & MDB_TXN_RDONLY) ? 'r' : 'w',
         (void*)txn,
         (void*)txn->mt_env,
         txn->mt_dbs[MAIN_DBI].md_root));
  }
  return rc;
}

int mdb_txn_begin(
    MDB_env* env,
    MDB_txn* parent,
    unsigned int flags,
    MDB_txn** ret) {
  MDB_txn* txn;
  MDB_ntxn* ntxn;
  int rc, size, tsize;

  flags &= MDB_TXN_BEGIN_FLAGS;
  flags |= env->me_flags & MDB_WRITEMAP;

  if (env->me_flags & MDB_RDONLY & ~flags) /* write txn in RDONLY env */
    return EACCES;

  if (parent) {
    /* Nested transactions: Max 1 child, write txns only, no writemap */
    flags |= parent->mt_flags;
    if (flags & (MDB_RDONLY | MDB_WRITEMAP | MDB_TXN_BLOCKED)) {
      return (parent->mt_flags & MDB_TXN_RDONLY) ? EINVAL : MDB_BAD_TXN;
    }
    /* Child txns save MDB_pgstate and use own copy of cursors */
    size = env->me_maxdbs * (sizeof(MDB_db) + sizeof(MDB_cursor*) + 1);
    size += tsize = sizeof(MDB_ntxn);
  } else if (flags & MDB_RDONLY) {
    size = env->me_maxdbs * (sizeof(MDB_db) + 1);
    size += tsize = sizeof(MDB_txn);
  } else {
    /* Reuse preallocated write txn. However, do not touch it until
     * mdb_txn_renew0() succeeds, since it currently may be active.
     */
    txn = env->me_txn0;
    goto renew;
  }
  if ((txn = calloc(1, size)) == NULL) {
    DPRINTF(("calloc: %s", strerror(errno)));
    return ENOMEM;
  }
#ifdef MDB_VL32
  if (!parent) {
    txn->mt_rpages = malloc(MDB_TRPAGE_SIZE * sizeof(MDB_ID3));
    if (!txn->mt_rpages) {
      free(txn);
      return ENOMEM;
    }
    txn->mt_rpages[0].mid = 0;
    txn->mt_rpcheck = MDB_TRPAGE_SIZE / 2;
  }
#endif
  txn->mt_dbxs = env->me_dbxs; /* static */
  txn->mt_dbs = (MDB_db*)((char*)txn + tsize);
  txn->mt_dbflags = (unsigned char*)txn + size - env->me_maxdbs;
  txn->mt_flags = flags;
  txn->mt_env = env;

  if (parent) {
    unsigned int i;
    txn->mt_cursors = (MDB_cursor**)(txn->mt_dbs + env->me_maxdbs);
    txn->mt_dbiseqs = parent->mt_dbiseqs;
    txn->mt_u.dirty_list = malloc(sizeof(MDB_ID2) * MDB_IDL_UM_SIZE);
    if (!txn->mt_u.dirty_list ||
        !(txn->mt_free_pgs = mdb_midl_alloc(MDB_IDL_UM_MAX))) {
      free(txn->mt_u.dirty_list);
      free(txn);
      return ENOMEM;
    }
    txn->mt_txnid = parent->mt_txnid;
    txn->mt_dirty_room = parent->mt_dirty_room;
    txn->mt_u.dirty_list[0].mid = 0;
    txn->mt_spill_pgs = NULL;
    txn->mt_next_pgno = parent->mt_next_pgno;
    parent->mt_flags |= MDB_TXN_HAS_CHILD;
    parent->mt_child = txn;
    txn->mt_parent = parent;
    txn->mt_numdbs = parent->mt_numdbs;
#ifdef MDB_VL32
    txn->mt_rpages = parent->mt_rpages;
#endif
    memcpy(txn->mt_dbs, parent->mt_dbs, txn->mt_numdbs * sizeof(MDB_db));
    /* Copy parent's mt_dbflags, but clear DB_NEW */
    for (i = 0; i < txn->mt_numdbs; i++)
      txn->mt_dbflags[i] = parent->mt_dbflags[i] & ~DB_NEW;
    rc = 0;
    ntxn = (MDB_ntxn*)txn;
    ntxn->mnt_pgstate = env->me_pgstate; /* save parent me_pghead & co */
    if (env->me_pghead) {
      size = MDB_IDL_SIZEOF(env->me_pghead);
      env->me_pghead = mdb_midl_alloc(env->me_pghead[0]);
      if (env->me_pghead)
        memcpy(env->me_pghead, ntxn->mnt_pgstate.mf_pghead, size);
      else
        rc = ENOMEM;
    }
    if (!rc)
      rc = mdb_cursor_shadow(parent, txn);
    if (rc)
      mdb_txn_end(txn, MDB_END_FAIL_BEGINCHILD);
  } else { /* MDB_RDONLY */
    txn->mt_dbiseqs = env->me_dbiseqs;
  renew:
    rc = mdb_txn_renew0(txn);
  }
  if (rc) {
    if (txn != env->me_txn0) {
      /* mt_rpages is owned by parent */
      free(txn->mt_u.dirty_list);
      free(txn);
    }
  } else {
    txn->mt_flags |= flags; /* could not change txn=me_txn0 earlier */
    *ret = txn;
    DPRINTF(
        ("begin txn %" Yu "%c %p on mdbenv %p, root page %" Yu,
         txn->mt_txnid,
         (flags & MDB_RDONLY) ? 'r' : 'w',
         (void*)txn,
         (void*)env,
         txn->mt_dbs[MAIN_DBI].md_root));
  }
  MDB_TRACE(("%p, %p, %u = %p", env, parent, flags, txn));

  return rc;
}

MDB_env* mdb_txn_env(MDB_txn* txn) {
  if (!txn)
    return NULL;
  return txn->mt_env;
}

mdb_size_t mdb_txn_id(MDB_txn* txn) {
  if (!txn)
    return 0;
  return txn->mt_txnid;
}

/** Export or close DBI handles opened in this txn. */
static void mdb_dbis_update(MDB_txn* txn, int keep) {
  int i;
  MDB_dbi n = txn->mt_numdbs;
  MDB_env* env = txn->mt_env;
  unsigned char* tdbflags = txn->mt_dbflags;

  for (i = n; --i >= CORE_DBS;) {
    if (tdbflags[i] & DB_NEW) {
      if (keep) {
        env->me_dbflags[i] = txn->mt_dbs[i].md_flags | MDB_VALID;
      } else {
        char* ptr = env->me_dbxs[i].md_name.mv_data;
        if (ptr) {
          env->me_dbxs[i].md_name.mv_data = NULL;
          env->me_dbxs[i].md_name.mv_size = 0;
          env->me_dbflags[i] = 0;
          env->me_dbiseqs[i]++;
          free(ptr);
        }
      }
    }
  }
  if (keep && env->me_numdbs < n)
    env->me_numdbs = n;
}

/** End a transaction, except successful commit of a nested transaction.
 * May be called twice for readonly txns: First reset it, then abort.
 * @param[in] txn the transaction handle to end
 * @param[in] mode why and how to end the transaction
 */
static void mdb_txn_end(MDB_txn* txn, unsigned mode) {
  MDB_env* env = txn->mt_env;
#if MDB_DEBUG
  static const char* const names[] = MDB_END_NAMES;
#endif

  /* Export or close DBI handles opened in this txn */
  mdb_dbis_update(txn, mode & MDB_END_UPDATE);

  DPRINTF(
      ("%s txn %" Yu "%c %p on mdbenv %p, root page %" Yu,
       names[mode & MDB_END_OPMASK],
       txn->mt_txnid,
       (txn->mt_flags & MDB_TXN_RDONLY) ? 'r' : 'w',
       (void*)txn,
       (void*)env,
       txn->mt_dbs[MAIN_DBI].md_root));

  if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY)) {
    if (txn->mt_u.reader) {
      txn->mt_u.reader->mr_txnid = (txnid_t)-1;
      if (!(env->me_flags & MDB_NOTLS)) {
        txn->mt_u.reader = NULL; /* txn does not own reader */
      } else if (mode & MDB_END_SLOT) {
        txn->mt_u.reader->mr_pid = 0;
        txn->mt_u.reader = NULL;
      } /* else txn owns the slot until it does MDB_END_SLOT */
    }
    txn->mt_numdbs = 0; /* prevent further DBI activity */
    txn->mt_flags |= MDB_TXN_FINISHED;

  } else if (!F_ISSET(txn->mt_flags, MDB_TXN_FINISHED)) {
    pgno_t* pghead = env->me_pghead;

    if (!(mode & MDB_END_UPDATE)) /* !(already closed cursors) */
      mdb_cursors_close(txn, 0);
    if (!(env->me_flags & MDB_WRITEMAP)) {
      mdb_dlist_free(txn);
    }

    txn->mt_numdbs = 0;
    txn->mt_flags = MDB_TXN_FINISHED;
    mdb_midl_free(txn->mt_spill_pgs);

    if (!txn->mt_parent) {
      mdb_midl_shrink(&txn->mt_free_pgs);
      env->me_free_pgs = txn->mt_free_pgs;
      /* me_pgstate: */
      env->me_pghead = NULL;
      env->me_pglast = 0;

      env->me_txn = NULL;
      mode = 0; /* txn == env->me_txn0, do not free() it */

      /* The writer mutex was locked in mdb_txn_begin. */
      if (env->me_txns)
        UNLOCK_MUTEX(env->me_wmutex);
    } else {
      txn->mt_parent->mt_child = NULL;
      txn->mt_parent->mt_flags &= ~MDB_TXN_HAS_CHILD;
      env->me_pgstate = ((MDB_ntxn*)txn)->mnt_pgstate;
      mdb_midl_free(txn->mt_free_pgs);
      free(txn->mt_u.dirty_list);
    }

    mdb_midl_free(pghead);
  }
#ifdef MDB_VL32
  if (!txn->mt_parent) {
    MDB_ID3L el = env->me_rpages, tl = txn->mt_rpages;
    unsigned i, x, n = tl[0].mid;
    pthread_mutex_lock(&env->me_rpmutex);
    for (i = 1; i <= n; i++) {
      if (tl[i].mid & (MDB_RPAGE_CHUNK - 1)) {
        /* tmp overflow pages that we didn't share in env */
        munmap(tl[i].mptr, tl[i].mcnt * env->me_psize);
      } else {
        x = mdb_mid3l_search(el, tl[i].mid);
        if (tl[i].mptr == el[x].mptr) {
          el[x].mref--;
        } else {
          /* another tmp overflow page */
          munmap(tl[i].mptr, tl[i].mcnt * env->me_psize);
        }
      }
    }
    pthread_mutex_unlock(&env->me_rpmutex);
    tl[0].mid = 0;
    if (mode & MDB_END_FREE)
      free(tl);
  }
#endif
  if (mode & MDB_END_FREE)
    free(txn);
}

void mdb_txn_reset(MDB_txn* txn) {
  if (txn == NULL)
    return;

  /* This call is only valid for read-only txns */
  if (!(txn->mt_flags & MDB_TXN_RDONLY))
    return;

  mdb_txn_end(txn, MDB_END_RESET);
}

static void _mdb_txn_abort(MDB_txn* txn) {
  if (txn == NULL)
    return;

  if (txn->mt_child)
    _mdb_txn_abort(txn->mt_child);

  mdb_txn_end(txn, MDB_END_ABORT | MDB_END_SLOT | MDB_END_FREE);
}

void mdb_txn_abort(MDB_txn* txn) {
  MDB_TRACE(("%p", txn));
  _mdb_txn_abort(txn);
}

/** Save the freelist as of this transaction to the freeDB.
 * This changes the freelist. Keep trying until it stabilizes.
 *
 * When (MDB_DEVEL) & 2, the changes do not affect #mdb_page_alloc(),
 * it then uses the transaction's original snapshot of the freeDB.
 */
static int mdb_freelist_save(MDB_txn* txn) {
  /* env->me_pghead[] can grow and shrink during this call.
   * env->me_pglast and txn->mt_free_pgs[] can only grow.
   * Page numbers cannot disappear from txn->mt_free_pgs[].
   */
  MDB_cursor mc;
  MDB_env* env = txn->mt_env;
  int rc, maxfree_1pg = env->me_maxfree_1pg, more = 1;
  txnid_t pglast = 0, head_id = 0;
  pgno_t freecnt = 0, *free_pgs, *mop;
  ssize_t head_room = 0, total_room = 0, mop_len, clean_limit;

  mdb_cursor_init(&mc, txn, FREE_DBI, NULL);

  if (env->me_pghead) {
    /* Make sure first page of freeDB is touched and on freelist */
    rc = mdb_page_search(&mc, NULL, MDB_PS_FIRST | MDB_PS_MODIFY);
    if (rc && rc != MDB_NOTFOUND)
      return rc;
  }

  if (!env->me_pghead && txn->mt_loose_pgs) {
    /* Put loose page numbers in mt_free_pgs, since
     * we may be unable to return them to me_pghead.
     */
    MDB_page* mp = txn->mt_loose_pgs;
    MDB_ID2* dl = txn->mt_u.dirty_list;
    unsigned x;
    if ((rc = mdb_midl_need(&txn->mt_free_pgs, txn->mt_loose_count)) != 0)
      return rc;
    for (; mp; mp = NEXT_LOOSE_PAGE(mp)) {
      mdb_midl_xappend(txn->mt_free_pgs, mp->mp_pgno);
      /* must also remove from dirty list */
      if (txn->mt_flags & MDB_TXN_WRITEMAP) {
        for (x = 1; x <= dl[0].mid; x++)
          if (dl[x].mid == mp->mp_pgno)
            break;
        mdb_tassert(txn, x <= dl[0].mid);
      } else {
        x = mdb_mid2l_search(dl, mp->mp_pgno);
        mdb_tassert(txn, dl[x].mid == mp->mp_pgno);
        mdb_dpage_free(env, mp);
      }
      dl[x].mptr = NULL;
    }
    {
      /* squash freed slots out of the dirty list */
      unsigned y;
      for (y = 1; dl[y].mptr && y <= dl[0].mid; y++)
        ;
      if (y <= dl[0].mid) {
        for (x = y, y++;;) {
          while (!dl[y].mptr && y <= dl[0].mid)
            y++;
          if (y > dl[0].mid)
            break;
          dl[x++] = dl[y++];
        }
        dl[0].mid = x - 1;
      } else {
        /* all slots freed */
        dl[0].mid = 0;
      }
    }
    txn->mt_loose_pgs = NULL;
    txn->mt_loose_count = 0;
  }

  /* MDB_RESERVE cancels meminit in ovpage malloc (when no WRITEMAP) */
  clean_limit = (env->me_flags & (MDB_NOMEMINIT | MDB_WRITEMAP)) ? SSIZE_MAX
                                                                 : maxfree_1pg;

  for (;;) {
    /* Come back here after each Put() in case freelist changed */
    MDB_val key, data;
    pgno_t* pgs;
    ssize_t j;

    /* If using records from freeDB which we have not yet
     * deleted, delete them and any we reserved for me_pghead.
     */
    while (pglast < env->me_pglast) {
      rc = mdb_cursor_first(&mc, &key, NULL);
      if (rc)
        return rc;
      pglast = head_id = *(txnid_t*)key.mv_data;
      total_room = head_room = 0;
      mdb_tassert(txn, pglast <= env->me_pglast);
      rc = _mdb_cursor_del(&mc, 0);
      if (rc)
        return rc;
    }

    /* Save the IDL of pages freed by this txn, to a single record */
    if (freecnt < txn->mt_free_pgs[0]) {
      if (!freecnt) {
        /* Make sure last page of freeDB is touched and on freelist */
        rc = mdb_page_search(&mc, NULL, MDB_PS_LAST | MDB_PS_MODIFY);
        if (rc && rc != MDB_NOTFOUND)
          return rc;
      }
      free_pgs = txn->mt_free_pgs;
      /* Write to last page of freeDB */
      key.mv_size = sizeof(txn->mt_txnid);
      key.mv_data = &txn->mt_txnid;
      do {
        freecnt = free_pgs[0];
        data.mv_size = MDB_IDL_SIZEOF(free_pgs);
        rc = _mdb_cursor_put(&mc, &key, &data, MDB_RESERVE);
        if (rc)
          return rc;
        /* Retry if mt_free_pgs[] grew during the Put() */
        free_pgs = txn->mt_free_pgs;
      } while (freecnt < free_pgs[0]);
      mdb_midl_sort(free_pgs);
      memcpy(data.mv_data, free_pgs, data.mv_size);
#if (MDB_DEBUG) > 1
      {
        unsigned int i = free_pgs[0];
        DPRINTF(
            ("IDL write txn %" Yu " root %" Yu " num %u",
             txn->mt_txnid,
             txn->mt_dbs[FREE_DBI].md_root,
             i));
        for (; i; i--)
          DPRINTF(("IDL %" Yu, free_pgs[i]));
      }
#endif
      continue;
    }

    mop = env->me_pghead;
    mop_len = (mop ? mop[0] : 0) + txn->mt_loose_count;

    /* Reserve records for me_pghead[]. Split it if multi-page,
     * to avoid searching freeDB for a page range. Use keys in
     * range [1,me_pglast]: Smaller than txnid of oldest reader.
     */
    if (total_room >= mop_len) {
      if (total_room == mop_len || --more < 0)
        break;
    } else if (head_room >= maxfree_1pg && head_id > 1) {
      /* Keep current record (overflow page), add a new one */
      head_id--;
      head_room = 0;
    }
    /* (Re)write {key = head_id, IDL length = head_room} */
    total_room -= head_room;
    head_room = mop_len - total_room;
    if (head_room > maxfree_1pg && head_id > 1) {
      /* Overflow multi-page for part of me_pghead */
      head_room /= head_id; /* amortize page sizes */
      head_room += maxfree_1pg - head_room % (maxfree_1pg + 1);
    } else if (head_room < 0) {
      /* Rare case, not bothering to delete this record */
      head_room = 0;
    }
    key.mv_size = sizeof(head_id);
    key.mv_data = &head_id;
    data.mv_size = (head_room + 1) * sizeof(pgno_t);
    rc = _mdb_cursor_put(&mc, &key, &data, MDB_RESERVE);
    if (rc)
      return rc;
    /* IDL is initially empty, zero out at least the length */
    pgs = (pgno_t*)data.mv_data;
    j = head_room > clean_limit ? head_room : 0;
    do {
      pgs[j] = 0;
    } while (--j >= 0);
    total_room += head_room;
  }

  /* Return loose page numbers to me_pghead, though usually none are
   * left at this point.  The pages themselves remain in dirty_list.
   */
  if (txn->mt_loose_pgs) {
    MDB_page* mp = txn->mt_loose_pgs;
    unsigned count = txn->mt_loose_count;
    MDB_IDL loose;
    /* Room for loose pages + temp IDL with same */
    if ((rc = mdb_midl_need(&env->me_pghead, 2 * count + 1)) != 0)
      return rc;
    mop = env->me_pghead;
    loose = mop + MDB_IDL_ALLOCLEN(mop) - count;
    for (count = 0; mp; mp = NEXT_LOOSE_PAGE(mp))
      loose[++count] = mp->mp_pgno;
    loose[0] = count;
    mdb_midl_sort(loose);
    mdb_midl_xmerge(mop, loose);
    txn->mt_loose_pgs = NULL;
    txn->mt_loose_count = 0;
    mop_len = mop[0];
  }

  /* Fill in the reserved me_pghead records */
  rc = MDB_SUCCESS;
  if (mop_len) {
    MDB_val key, data;

    mop += mop_len;
    rc = mdb_cursor_first(&mc, &key, &data);
    for (; !rc; rc = mdb_cursor_next(&mc, &key, &data, MDB_NEXT)) {
      txnid_t id = *(txnid_t*)key.mv_data;
      ssize_t len = (ssize_t)(data.mv_size / sizeof(MDB_ID)) - 1;
      MDB_ID save;

      mdb_tassert(txn, len >= 0 && id <= env->me_pglast);
      key.mv_data = &id;
      if (len > mop_len) {
        len = mop_len;
        data.mv_size = (len + 1) * sizeof(MDB_ID);
      }
      data.mv_data = mop -= len;
      save = mop[0];
      mop[0] = len;
      rc = _mdb_cursor_put(&mc, &key, &data, MDB_CURRENT);
      mop[0] = save;
      if (rc || !(mop_len -= len))
        break;
    }
  }
  return rc;
}

/** Flush (some) dirty pages to the map, after clearing their dirty flag.
 * @param[in] txn the transaction that's being committed
 * @param[in] keep number of initial pages in dirty_list to keep dirty.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_flush(MDB_txn* txn, int keep) {
  MDB_env* env = txn->mt_env;
  MDB_ID2L dl = txn->mt_u.dirty_list;
  unsigned psize = env->me_psize, j;
  int i, pagecount = dl[0].mid, rc;
  size_t size = 0;
  MDB_OFF_T pos = 0;
  pgno_t pgno = 0;
  MDB_page* dp = NULL;
#ifdef _WIN32
  OVERLAPPED* ov = env->ov;
  MDB_page* wdp;
  int async_i = 0;
  HANDLE fd = (env->me_flags & MDB_NOSYNC) ? env->me_fd : env->me_ovfd;
#else
  struct iovec iov[MDB_COMMIT_PAGES];
  HANDLE fd = env->me_fd;
#endif
  ssize_t wsize = 0, wres;
  MDB_OFF_T wpos = 0, next_pos = 1; /* impossible pos, so pos != next_pos */
  int n = 0;

  j = i = keep;
  if (env->me_flags & MDB_WRITEMAP
#ifdef _WIN32
      /* In windows, we still do writes to the file (with write-through enabled
       * in sync mode), as this is faster than FlushViewOfFile/FlushFileBuffers
       */
      && (env->me_flags & MDB_NOSYNC)
#endif
  ) {
    /* Clear dirty flags */
    while (++i <= pagecount) {
      dp = dl[i].mptr;
      /* Don't flush this page yet */
      if (dp->mp_flags & (P_LOOSE | P_KEEP)) {
        dp->mp_flags &= ~P_KEEP;
        dl[++j] = dl[i];
        continue;
      }
      dp->mp_flags &= ~P_DIRTY;
    }
    goto done;
  }

#ifdef _WIN32
  if (pagecount - keep >= env->ovs) {
    /* ran out of room in ov array, and re-malloc, copy handles and free
     * previous */
    int ovs = (pagecount - keep) *
        1.5; /* provide extra padding to reduce number of re-allocations */
    int new_size = ovs * sizeof(OVERLAPPED);
    ov = malloc(new_size);
    if (ov == NULL)
      return ENOMEM;
    int previous_size = env->ovs * sizeof(OVERLAPPED);
    memcpy(ov, env->ov, previous_size); /* Copy previous OVERLAPPED data to
                                           retain event handles */
    /* And clear rest of memory */
    memset(&ov[env->ovs], 0, new_size - previous_size);
    if (env->ovs > 0) {
      free(env->ov); /* release previous allocation */
    }

    env->ov = ov;
    env->ovs = ovs;
  }
#endif

  /* Write the pages */
  for (;;) {
    if (++i <= pagecount) {
      dp = dl[i].mptr;
      /* Don't flush this page yet */
      if (dp->mp_flags & (P_LOOSE | P_KEEP)) {
        dp->mp_flags &= ~P_KEEP;
        dl[i].mid = 0;
        continue;
      }
      pgno = dl[i].mid;
      /* clear dirty flag */
      dp->mp_flags &= ~P_DIRTY;
      pos = pgno * psize;
      size = psize;
      if (IS_OVERFLOW(dp))
        size *= dp->mp_pages;
    }
    /* Write up to MDB_COMMIT_PAGES dirty pages at a time. */
    if (pos != next_pos || n == MDB_COMMIT_PAGES ||
        wsize + size > MAX_WRITE
#ifdef _WIN32
        /* If writemap is enabled, consecutive page positions infer
         * contiguous (mapped) memory.
         * Otherwise force write pages one at a time.
         * 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.
         */
        || !(env->me_flags & MDB_WRITEMAP)
#endif
    ) {
      if (n) {
      retry_write:
        /* Write previous page(s) */
        DPRINTF(("committing page %" Z "u", pgno));
#ifdef _WIN32
        OVERLAPPED* this_ov = &ov[async_i];
        /* Clear status, and keep hEvent, we reuse that */
        this_ov->Internal = 0;
        this_ov->Offset = wpos & 0xffffffff;
        this_ov->OffsetHigh = wpos >> 16 >> 16;
        if (!F_ISSET(env->me_flags, MDB_NOSYNC) && !this_ov->hEvent) {
          HANDLE event = CreateEvent(NULL, FALSE, FALSE, NULL);
          if (!event) {
            rc = ErrCode();
            DPRINTF(("CreateEvent: %s", strerror(rc)));
            return rc;
          }
          this_ov->hEvent = event;
        }
        if (!WriteFile(fd, wdp, wsize, NULL, this_ov)) {
          rc = ErrCode();
          if (rc != ERROR_IO_PENDING) {
            DPRINTF(("WriteFile: %d", rc));
            return rc;
          }
        }
        async_i++;
#else
#ifdef MDB_USE_PWRITEV
        wres = pwritev(fd, iov, n, wpos);
#else
        if (n == 1) {
          wres = pwrite(fd, iov[0].iov_base, wsize, wpos);
        } else {
        retry_seek:
          if (lseek(fd, wpos, SEEK_SET) == -1) {
            rc = ErrCode();
            if (rc == EINTR)
              goto retry_seek;
            DPRINTF(("lseek: %s", strerror(rc)));
            return rc;
          }
          wres = writev(fd, iov, n);
        }
#endif
        if (wres != wsize) {
          if (wres < 0) {
            rc = ErrCode();
            if (rc == EINTR)
              goto retry_write;
            DPRINTF(("Write error: %s", strerror(rc)));
          } else {
            rc = EIO; /* TODO: Use which error code? */
            DPUTS("short write, filesystem full?");
          }
          return rc;
        }
#endif /* _WIN32 */
        n = 0;
      }
      if (i > pagecount)
        break;
      wpos = pos;
      wsize = 0;
#ifdef _WIN32
      wdp = dp;
    }
#else
    }
    iov[n].iov_len = size;
    iov[n].iov_base = (char*)dp;
#endif /* _WIN32 */
    DPRINTF(("committing page %" Yu, pgno));
    next_pos = pos + size;
    wsize += size;
    n++;
  }
#ifdef MDB_VL32
  if (pgno > txn->mt_last_pgno)
    txn->mt_last_pgno = pgno;
#endif

#ifdef _WIN32
  if (!F_ISSET(env->me_flags, MDB_NOSYNC)) {
    /* Now wait for all the asynchronous/overlapped sync/write-through writes to
     * complete. We start with the last one so that all the others should
     * already be complete and we reduce thread suspend/resuming (in practice,
     * typically about 99.5% of writes are done after the last write is done) */
    rc = 0;
    while (--async_i >= 0) {
      if (ov[async_i].hEvent) {
        DWORD temp_wres;
        if (!GetOverlappedResult(fd, &ov[async_i], &temp_wres, TRUE)) {
          rc = ErrCode(); /* Continue on so that all the event signals are reset
                           */
        }
        wres = temp_wres;
      }
    }
    if (rc) { /* any error on GetOverlappedResult, exit now */
      return rc;
    }
  }
#endif /* _WIN32 */

  if (!(env->me_flags & MDB_WRITEMAP)) {
    /* Don't free pages when using writemap (can only get here in NOSYNC mode in
     * Windows) MIPS has cache coherency issues, this is a no-op everywhere else
     * Note: for any size >= on-chip cache size, entire on-chip cache is
     * flushed.
     */
    CACHEFLUSH(env->me_map, txn->mt_next_pgno * env->me_psize, DCACHE);

    for (i = keep; ++i <= pagecount;) {
      dp = dl[i].mptr;
      /* This is a page we skipped above */
      if (!dl[i].mid) {
        dl[++j] = dl[i];
        dl[j].mid = dp->mp_pgno;
        continue;
      }
      mdb_dpage_free(env, dp);
    }
  }

done:
  i--;
  txn->mt_dirty_room += i - j;
  dl[0].mid = j;
  return MDB_SUCCESS;
}

static int ESECT mdb_env_share_locks(MDB_env* env, int* excl);

static int _mdb_txn_commit(MDB_txn* txn) {
  int rc;
  unsigned int i, end_mode;
  MDB_env* env;

  if (txn == NULL)
    return EINVAL;

  /* mdb_txn_end() mode for a commit which writes nothing */
  end_mode =
      MDB_END_EMPTY_COMMIT | MDB_END_UPDATE | MDB_END_SLOT | MDB_END_FREE;

  if (txn->mt_child) {
    rc = _mdb_txn_commit(txn->mt_child);
    if (rc)
      goto fail;
  }

  env = txn->mt_env;

  if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY)) {
    goto done;
  }

  if (txn->mt_flags & (MDB_TXN_FINISHED | MDB_TXN_ERROR)) {
    DPUTS("txn has failed/finished, can't commit");
    if (txn->mt_parent)
      txn->mt_parent->mt_flags |= MDB_TXN_ERROR;
    rc = MDB_BAD_TXN;
    goto fail;
  }

  if (txn->mt_parent) {
    MDB_txn* parent = txn->mt_parent;
    MDB_page** lp;
    MDB_ID2L dst, src;
    MDB_IDL pspill;
    unsigned x, y, len, ps_len;

    /* Append our free list to parent's */
    rc = mdb_midl_append_list(&parent->mt_free_pgs, txn->mt_free_pgs);
    if (rc)
      goto fail;
    mdb_midl_free(txn->mt_free_pgs);
    /* Failures after this must either undo the changes
     * to the parent or set MDB_TXN_ERROR in the parent.
     */

    parent->mt_next_pgno = txn->mt_next_pgno;
    parent->mt_flags = txn->mt_flags;

    /* Merge our cursors into parent's and close them */
    mdb_cursors_close(txn, 1);

    /* Update parent's DB table. */
    memcpy(parent->mt_dbs, txn->mt_dbs, txn->mt_numdbs * sizeof(MDB_db));
    parent->mt_numdbs = txn->mt_numdbs;
    parent->mt_dbflags[FREE_DBI] = txn->mt_dbflags[FREE_DBI];
    parent->mt_dbflags[MAIN_DBI] = txn->mt_dbflags[MAIN_DBI];
    for (i = CORE_DBS; i < txn->mt_numdbs; i++) {
      /* preserve parent's DB_NEW status */
      x = parent->mt_dbflags[i] & DB_NEW;
      parent->mt_dbflags[i] = txn->mt_dbflags[i] | x;
    }

    dst = parent->mt_u.dirty_list;
    src = txn->mt_u.dirty_list;
    /* Remove anything in our dirty list from parent's spill list */
    if ((pspill = parent->mt_spill_pgs) && (ps_len = pspill[0])) {
      x = y = ps_len;
      pspill[0] = (pgno_t)-1;
      /* Mark our dirty pages as deleted in parent spill list */
      for (i = 0, len = src[0].mid; ++i <= len;) {
        MDB_ID pn = src[i].mid << 1;
        while (pn > pspill[x])
          x--;
        if (pn == pspill[x]) {
          pspill[x] = 1;
          y = --x;
        }
      }
      /* Squash deleted pagenums if we deleted any */
      for (x = y; ++x <= ps_len;)
        if (!(pspill[x] & 1))
          pspill[++y] = pspill[x];
      pspill[0] = y;
    }

    /* Remove anything in our spill list from parent's dirty list */
    if (txn->mt_spill_pgs && txn->mt_spill_pgs[0]) {
      for (i = 1; i <= txn->mt_spill_pgs[0]; i++) {
        MDB_ID pn = txn->mt_spill_pgs[i];
        if (pn & 1)
          continue; /* deleted spillpg */
        pn >>= 1;
        y = mdb_mid2l_search(dst, pn);
        if (y <= dst[0].mid && dst[y].mid == pn) {
          free(dst[y].mptr);
          while (y < dst[0].mid) {
            dst[y] = dst[y + 1];
            y++;
          }
          dst[0].mid--;
        }
      }
    }

    /* Find len = length of merging our dirty list with parent's */
    x = dst[0].mid;
    dst[0].mid = 0; /* simplify loops */
    if (parent->mt_parent) {
      len = x + src[0].mid;
      y = mdb_mid2l_search(src, dst[x].mid + 1) - 1;
      for (i = x; y && i; y--) {
        pgno_t yp = src[y].mid;
        while (yp < dst[i].mid)
          i--;
        if (yp == dst[i].mid) {
          i--;
          len--;
        }
      }
    } else { /* Simplify the above for single-ancestor case */
      len = MDB_IDL_UM_MAX - txn->mt_dirty_room;
    }
    /* Merge our dirty list with parent's */
    y = src[0].mid;
    for (i = len; y; dst[i--] = src[y--]) {
      pgno_t yp = src[y].mid;
      while (yp < dst[x].mid)
        dst[i--] = dst[x--];
      if (yp == dst[x].mid)
        free(dst[x--].mptr);
    }
    mdb_tassert(txn, i == x);
    dst[0].mid = len;
    free(txn->mt_u.dirty_list);
    parent->mt_dirty_room = txn->mt_dirty_room;
    if (txn->mt_spill_pgs) {
      if (parent->mt_spill_pgs) {
        /* TODO: Prevent failure here, so parent does not fail */
        rc = mdb_midl_append_list(&parent->mt_spill_pgs, txn->mt_spill_pgs);
        if (rc)
          parent->mt_flags |= MDB_TXN_ERROR;
        mdb_midl_free(txn->mt_spill_pgs);
        mdb_midl_sort(parent->mt_spill_pgs);
      } else {
        parent->mt_spill_pgs = txn->mt_spill_pgs;
      }
    }

    /* Append our loose page list to parent's */
    for (lp = &parent->mt_loose_pgs; *lp; lp = &NEXT_LOOSE_PAGE(*lp))
      ;
    *lp = txn->mt_loose_pgs;
    parent->mt_loose_count += txn->mt_loose_count;

    parent->mt_child = NULL;
    mdb_midl_free(((MDB_ntxn*)txn)->mnt_pgstate.mf_pghead);
    free(txn);
    return rc;
  }

  if (txn != env->me_txn) {
    DPUTS("attempt to commit unknown transaction");
    rc = EINVAL;
    goto fail;
  }

  mdb_cursors_close(txn, 0);

  if (!txn->mt_u.dirty_list[0].mid &&
      !(txn->mt_flags & (MDB_TXN_DIRTY | MDB_TXN_SPILLS)))
    goto done;

  DPRINTF(
      ("committing txn %" Yu " %p on mdbenv %p, root page %" Yu,
       txn->mt_txnid,
       (void*)txn,
       (void*)env,
       txn->mt_dbs[MAIN_DBI].md_root));

  /* Update DB root pointers */
  if (txn->mt_numdbs > CORE_DBS) {
    MDB_cursor mc;
    MDB_dbi i;
    MDB_val data;
    data.mv_size = sizeof(MDB_db);

    mdb_cursor_init(&mc, txn, MAIN_DBI, NULL);
    for (i = CORE_DBS; i < txn->mt_numdbs; i++) {
      if (txn->mt_dbflags[i] & DB_DIRTY) {
        if (TXN_DBI_CHANGED(txn, i)) {
          rc = MDB_BAD_DBI;
          goto fail;
        }
        data.mv_data = &txn->mt_dbs[i];
        rc = _mdb_cursor_put(&mc, &txn->mt_dbxs[i].md_name, &data, F_SUBDATA);
        if (rc)
          goto fail;
      }
    }
  }

  rc = mdb_freelist_save(txn);
  if (rc)
    goto fail;

  mdb_midl_free(env->me_pghead);
  env->me_pghead = NULL;
  mdb_midl_shrink(&txn->mt_free_pgs);

#if (MDB_DEBUG) > 2
  mdb_audit(txn);
#endif

  if ((rc = mdb_page_flush(txn, 0)))
    goto fail;
  if (!F_ISSET(txn->mt_flags, MDB_TXN_NOSYNC) &&
      (rc = mdb_env_sync0(env, 0, txn->mt_next_pgno)))
    goto fail;
  if ((rc = mdb_env_write_meta(txn)))
    goto fail;
  end_mode = MDB_END_COMMITTED | MDB_END_UPDATE;
  if (env->me_flags & MDB_PREVSNAPSHOT) {
    if (!(env->me_flags & MDB_NOLOCK)) {
      int excl;
      rc = mdb_env_share_locks(env, &excl);
      if (rc)
        goto fail;
    }
    env->me_flags ^= MDB_PREVSNAPSHOT;
  }

done:
  mdb_txn_end(txn, end_mode);
  return MDB_SUCCESS;

fail:
  _mdb_txn_abort(txn);
  return rc;
}

int mdb_txn_commit(MDB_txn* txn) {
  MDB_TRACE(("%p", txn));
  return _mdb_txn_commit(txn);
}

/** Read the environment parameters of a DB environment before
 * mapping it into memory.
 * @param[in] env the environment handle
 * @param[in] prev whether to read the backup meta page
 * @param[out] meta address of where to store the meta information
 * @return 0 on success, non-zero on failure.
 */
static int ESECT mdb_env_read_header(MDB_env* env, int prev, MDB_meta* meta) {
  MDB_metabuf pbuf;
  MDB_page* p;
  MDB_meta* m;
  int i, rc, off;
  enum { Size = sizeof(pbuf) };

  /* We don't know the page size yet, so use a minimum value.
   * Read both meta pages so we can use the latest one.
   */

  for (i = off = 0; i < NUM_METAS; i++, off += meta->mm_psize) {
#ifdef _WIN32
    DWORD len;
    OVERLAPPED ov;
    memset(&ov, 0, sizeof(ov));
    ov.Offset = off;
    rc = ReadFile(env->me_fd, &pbuf, Size, &len, &ov) ? (int)len : -1;
    if (rc == -1 && ErrCode() == ERROR_HANDLE_EOF)
      rc = 0;
#else
    rc = pread(env->me_fd, &pbuf, Size, off);
#endif
    if (rc != Size) {
      if (rc == 0 && off == 0)
        return ENOENT;
      rc = rc < 0 ? (int)ErrCode() : MDB_INVALID;
      DPRINTF(("read: %s", mdb_strerror(rc)));
      return rc;
    }

    p = (MDB_page*)&pbuf;

    if (!F_ISSET(p->mp_flags, P_META)) {
      DPRINTF(("page %" Yu " not a meta page", p->mp_pgno));
      return MDB_INVALID;
    }

    m = METADATA(p);
    if (m->mm_magic != MDB_MAGIC) {
      DPUTS("meta has invalid magic");
      return MDB_INVALID;
    }

    if (m->mm_version != MDB_DATA_VERSION) {
      DPRINTF(
          ("database is version %u, expected version %u",
           m->mm_version,
           MDB_DATA_VERSION));
      return MDB_VERSION_MISMATCH;
    }

    if (off == 0 ||
        (prev ? m->mm_txnid < meta->mm_txnid : m->mm_txnid > meta->mm_txnid))
      *meta = *m;
  }
  return 0;
}

/** Fill in most of the zeroed #MDB_meta for an empty database environment */
static void ESECT mdb_env_init_meta0(MDB_env* env, MDB_meta* meta) {
  meta->mm_magic = MDB_MAGIC;
  meta->mm_version = MDB_DATA_VERSION;
  meta->mm_mapsize = env->me_mapsize;
  meta->mm_psize = env->me_psize;
  meta->mm_last_pg = NUM_METAS - 1;
  meta->mm_flags = env->me_flags & 0xffff;
  meta->mm_flags |= MDB_INTEGERKEY; /* this is mm_dbs[FREE_DBI].md_flags */
  meta->mm_dbs[FREE_DBI].md_root = P_INVALID;
  meta->mm_dbs[MAIN_DBI].md_root = P_INVALID;
}

/** Write the environment parameters of a freshly created DB environment.
 * @param[in] env the environment handle
 * @param[in] meta the #MDB_meta to write
 * @return 0 on success, non-zero on failure.
 */
static int ESECT mdb_env_init_meta(MDB_env* env, MDB_meta* meta) {
  MDB_page *p, *q;
  int rc;
  unsigned int psize;
#ifdef _WIN32
  DWORD len;
  OVERLAPPED ov;
  memset(&ov, 0, sizeof(ov));
#define DO_PWRITE(rc, fd, ptr, size, len, pos) \
  do {                                         \
    ov.Offset = pos;                           \
    rc = WriteFile(fd, ptr, size, &len, &ov);  \
  } while (0)
#else
  int len;
#define DO_PWRITE(rc, fd, ptr, size, len, pos) \
  do {                                         \
    len = pwrite(fd, ptr, size, pos);          \
    if (len == -1 && ErrCode() == EINTR)       \
      continue;                                \
    rc = (len >= 0);                           \
    break;                                     \
  } while (1)
#endif
  DPUTS("writing new meta page");

  psize = env->me_psize;

  p = calloc(NUM_METAS, psize);
  if (!p)
    return ENOMEM;
  p->mp_pgno = 0;
  p->mp_flags = P_META;
  *(MDB_meta*)METADATA(p) = *meta;

  q = (MDB_page*)((char*)p + psize);
  q->mp_pgno = 1;
  q->mp_flags = P_META;
  *(MDB_meta*)METADATA(q) = *meta;

  DO_PWRITE(rc, env->me_fd, p, psize * NUM_METAS, len, 0);
  if (!rc)
    rc = ErrCode();
  else if ((unsigned)len == psize * NUM_METAS)
    rc = MDB_SUCCESS;
  else
    rc = ENOSPC;
  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, *mp;
  unsigned flags;
  mdb_size_t mapsize;
  MDB_OFF_T off;
  int rc, len, toggle;
  char* ptr;
  HANDLE mfd;
#ifdef _WIN32
  OVERLAPPED ov;
#else
  int r2;
#endif

  toggle = txn->mt_txnid & 1;
  DPRINTF(
      ("writing meta page %d for root page %" Yu,
       toggle,
       txn->mt_dbs[MAIN_DBI].md_root));

  env = txn->mt_env;
  flags = txn->mt_flags | env->me_flags;
  mp = env->me_metas[toggle];
  mapsize = env->me_metas[toggle ^ 1]->mm_mapsize;
  /* Persist any increases of mapsize config */
  if (mapsize < env->me_mapsize)
    mapsize = env->me_mapsize;

#ifndef _WIN32 /* We don't want to ever use MSYNC/FlushViewOfFile in Windows \
                */
  if (flags & MDB_WRITEMAP) {
    mp->mm_mapsize = mapsize;
    mp->mm_dbs[FREE_DBI] = txn->mt_dbs[FREE_DBI];
    mp->mm_dbs[MAIN_DBI] = txn->mt_dbs[MAIN_DBI];
    mp->mm_last_pg = txn->mt_next_pgno - 1;
#if (__GNUC__ * 100 + __GNUC_MINOR__ >= 404) && /* TODO: portability */ \
    !(defined(__i386__) || defined(__x86_64__))
    /* LY: issue a memory barrier, if not x86. ITS#7969 */
    __sync_synchronize();
#endif
    mp->mm_txnid = txn->mt_txnid;
    if (!(flags & (MDB_NOMETASYNC | MDB_NOSYNC))) {
      unsigned meta_size = env->me_psize;
      rc = (env->me_flags & MDB_MAPASYNC) ? MS_ASYNC : MS_SYNC;
      ptr = (char*)mp - PAGEHDRSZ;
      /* POSIX msync() requires ptr = start of OS page */
      r2 = (ptr - env->me_map) & (env->me_os_psize - 1);
      ptr -= r2;
      meta_size += r2;
      if (MDB_MSYNC(ptr, meta_size, rc)) {
        rc = ErrCode();
        goto fail;
      }
    }
    goto done;
  }
#endif
  metab.mm_txnid = mp->mm_txnid;
  metab.mm_last_pg = mp->mm_last_pg;

  meta.mm_mapsize = mapsize;
  meta.mm_dbs[FREE_DBI] = txn->mt_dbs[FREE_DBI];
  meta.mm_dbs[MAIN_DBI] = txn->mt_dbs[MAIN_DBI];
  meta.mm_last_pg = txn->mt_next_pgno - 1;
  meta.mm_txnid = txn->mt_txnid;

  off = offsetof(MDB_meta, mm_mapsize);
  ptr = (char*)&meta + off;
  len = sizeof(MDB_meta) - off;
  off += (char*)mp - env->me_map;

  /* Write to the SYNC fd unless MDB_NOSYNC/MDB_NOMETASYNC.
   * (me_mfd goes to the same file as me_fd, but writing to it
   * also syncs to disk.  Avoids a separate fdatasync() call.)
   */
  mfd = (flags & (MDB_NOSYNC | MDB_NOMETASYNC)) ? env->me_fd : env->me_mfd;
#ifdef _WIN32
  {
    memset(&ov, 0, sizeof(ov));
    ov.Offset = off;
    if (!WriteFile(mfd, ptr, len, (DWORD*)&rc, &ov))
      rc = -1;
  }
#else
retry_write:
  rc = pwrite(mfd, ptr, len, off);
#endif
  if (rc != len) {
    rc = rc < 0 ? ErrCode() : EIO;
#ifndef _WIN32
    if (rc == EINTR)
      goto retry_write;
#endif
    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
    memset(&ov, 0, sizeof(ov));
    ov.Offset = off;
    WriteFile(env->me_fd, ptr, len, NULL, &ov);
#else
    r2 = pwrite(env->me_fd, ptr, len, off);
    (void)r2; /* Silence warnings. We don't care about pwrite's return value */
#endif
  fail:
    env->me_flags |= MDB_FATAL_ERROR;
    return rc;
  }
  /* MIPS has cache coherency issues, this is a no-op everywhere else */
  CACHEFLUSH(env->me_map + off, len, DCACHE);
done:
  /* 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.
   */
  if (env->me_txns)
    env->me_txns->mti_txnid = txn->mt_txnid;

  return MDB_SUCCESS;
}

/** Check both meta pages to see which one is newer.
 * @param[in] env the environment handle
 * @return newest #MDB_meta.
 */
static MDB_meta* mdb_env_pick_meta(const MDB_env* env) {
  MDB_meta* const* metas = env->me_metas;
  return metas
      [(metas[0]->mm_txnid < metas[1]->mm_txnid) ^
       ((env->me_flags & MDB_PREVSNAPSHOT) != 0)];
}

int ESECT 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 = e->me_numdbs = CORE_DBS;
  e->me_fd = INVALID_HANDLE_VALUE;
  e->me_lfd = INVALID_HANDLE_VALUE;
  e->me_mfd = INVALID_HANDLE_VALUE;
#ifdef MDB_USE_POSIX_SEM
  e->me_rmutex = SEM_FAILED;
  e->me_wmutex = SEM_FAILED;
#elif defined MDB_USE_SYSV_SEM
  e->me_rmutex->semid = -1;
  e->me_wmutex->semid = -1;
#endif
  e->me_pid = getpid();
  GET_PAGESIZE(e->me_os_psize);
  VGMEMP_CREATE(e, 0, 0);
  *env = e;
  MDB_TRACE(("%p", e));
  return MDB_SUCCESS;
}

#ifdef _WIN32
/** @brief Map a result from an NTAPI call to WIN32. */
static DWORD mdb_nt2win32(NTSTATUS st) {
  OVERLAPPED o = {0};
  DWORD br;
  o.Internal = st;
  GetOverlappedResult(NULL, &o, &br, FALSE);
  return GetLastError();
}
#endif

static int ESECT mdb_env_map(MDB_env* env, void* addr) {
  MDB_page* p;
  unsigned int flags = env->me_flags;
#ifdef _WIN32
  int rc;
  int access = SECTION_MAP_READ;
  HANDLE mh;
  void* map;
  SIZE_T msize;
  ULONG pageprot = PAGE_READONLY, secprot, alloctype;

  if (flags & MDB_WRITEMAP) {
    access |= SECTION_MAP_WRITE;
    pageprot = PAGE_READWRITE;
  }
  if (flags & MDB_RDONLY) {
    secprot = PAGE_READONLY;
    msize = 0;
    alloctype = 0;
  } else {
    secprot = PAGE_READWRITE;
    msize = env->me_mapsize;
    alloctype = MEM_RESERVE;
  }

  /** Some users are afraid of seeing their disk space getting used
   * all at once, so the default is now to do incremental file growth.
   * But that has a large performance impact, so give the option of
   * allocating the file up front.
   */
#ifdef MDB_FIXEDSIZE
  LARGE_INTEGER fsize;
  fsize.LowPart = msize & 0xffffffff;
  fsize.HighPart = msize >> 16 >> 16;
  rc = NtCreateSection(
      &mh, access, NULL, &fsize, secprot, SEC_RESERVE, env->me_fd);
#else
  rc = NtCreateSection(
      &mh, access, NULL, NULL, secprot, SEC_RESERVE, env->me_fd);
#endif
  if (rc)
    return mdb_nt2win32(rc);
  map = addr;
#ifdef MDB_VL32
  msize = NUM_METAS * env->me_psize;
#endif
  rc = NtMapViewOfSection(
      mh,
      GetCurrentProcess(),
      &map,
      0,
      0,
      NULL,
      &msize,
      ViewUnmap,
      alloctype,
      pageprot);
#ifdef MDB_VL32
  env->me_fmh = mh;
#else
  NtClose(mh);
#endif
  if (rc)
    return mdb_nt2win32(rc);
  env->me_map = map;
#else
  int mmap_flags = MAP_SHARED;
  int prot = PROT_READ;
#ifdef MAP_NOSYNC /* Used on FreeBSD */
  if (flags & MDB_NOSYNC)
    mmap_flags |= MAP_NOSYNC;
#endif
#ifdef MDB_VL32
  (void)flags;
  env->me_map =
      mmap(addr, NUM_METAS * env->me_psize, prot, mmap_flags, env->me_fd, 0);
  if (env->me_map == MAP_FAILED) {
    env->me_map = NULL;
    return ErrCode();
  }
#else
  if (flags & MDB_WRITEMAP) {
    prot |= PROT_WRITE;
    if (ftruncate(env->me_fd, env->me_mapsize) < 0)
      return ErrCode();
  }
  env->me_map = mmap(addr, env->me_mapsize, prot, mmap_flags, env->me_fd, 0);
  if (env->me_map == MAP_FAILED) {
    env->me_map = NULL;
    return ErrCode();
  }

  if (flags & MDB_NORDAHEAD) {
    /* Turn off readahead. It's harmful when the DB is larger than RAM. */
#ifdef MADV_RANDOM
    madvise(env->me_map, env->me_mapsize, MADV_RANDOM);
#else
#ifdef POSIX_MADV_RANDOM
    posix_madvise(env->me_map, env->me_mapsize, POSIX_MADV_RANDOM);
#endif /* POSIX_MADV_RANDOM */
#endif /* MADV_RANDOM */
  }
#endif /* _WIN32 */

  /* Can happen because the address argument to mmap() is just a
   * hint.  mmap() can pick another, e.g. if the range is in use.
   * The MAP_FIXED flag would prevent that, but then mmap could
   * instead unmap existing pages to make room for the new map.
   */
  if (addr && env->me_map != addr)
    return EBUSY; /* TODO: Make a new MDB_* error code? */
#endif

  p = (MDB_page*)env->me_map;
  env->me_metas[0] = METADATA(p);
  env->me_metas[1] = (MDB_meta*)((char*)env->me_metas[0] + env->me_psize);

  return MDB_SUCCESS;
}

int ESECT mdb_env_set_mapsize(MDB_env* env, mdb_size_t size) {
  /* If env is already open, caller is responsible for making
   * sure there are no active txns.
   */
  if (env->me_map) {
    MDB_meta* meta;
#ifndef MDB_VL32
    void* old;
    int rc;
#endif
    if (env->me_txn)
      return EINVAL;
    meta = mdb_env_pick_meta(env);
    if (!size)
      size = meta->mm_mapsize;
    {
      /* Silently round up to minimum if the size is too small */
      mdb_size_t minsize = (meta->mm_last_pg + 1) * env->me_psize;
      if (size < minsize)
        size = minsize;
    }
#ifndef MDB_VL32
    /* For MDB_VL32 this bit is a noop since we dynamically remap
     * chunks of the DB anyway.
     */
    munmap(env->me_map, env->me_mapsize);
    env->me_mapsize = size;
    old = (env->me_flags & MDB_FIXEDMAP) ? env->me_map : NULL;
    rc = mdb_env_map(env, old);
    if (rc)
      return rc;
#endif /* !MDB_VL32 */
  }
  env->me_mapsize = size;
  if (env->me_psize)
    env->me_maxpg = env->me_mapsize / env->me_psize;
  MDB_TRACE(("%p, %" Yu "", env, size));
  return MDB_SUCCESS;
}

int ESECT mdb_env_set_maxdbs(MDB_env* env, MDB_dbi dbs) {
  if (env->me_map)
    return EINVAL;
  env->me_maxdbs = dbs + CORE_DBS;
  MDB_TRACE(("%p, %u", env, dbs));
  return MDB_SUCCESS;
}

int ESECT mdb_env_set_maxreaders(MDB_env* env, unsigned int readers) {
  if (env->me_map || readers < 1)
    return EINVAL;
  env->me_maxreaders = readers;
  MDB_TRACE(("%p, %u", env, readers));
  return MDB_SUCCESS;
}

int ESECT mdb_env_get_maxreaders(MDB_env* env, unsigned int* readers) {
  if (!env || !readers)
    return EINVAL;
  *readers = env->me_maxreaders;
  return MDB_SUCCESS;
}

static int ESECT mdb_fsize(HANDLE fd, mdb_size_t* size) {
#ifdef _WIN32
  LARGE_INTEGER fsize;

  if (!GetFileSizeEx(fd, &fsize))
    return ErrCode();

  *size = fsize.QuadPart;
#else
  struct stat st;

  if (fstat(fd, &st))
    return ErrCode();

  *size = st.st_size;
#endif
  return MDB_SUCCESS;
}

#ifdef _WIN32
typedef wchar_t mdb_nchar_t;
#define MDB_NAME(str) L##str
#define mdb_name_cpy wcscpy
#else
/** Character type for file names: char on Unix, wchar_t on Windows */
typedef char mdb_nchar_t;
#define MDB_NAME(str) str /**< #mdb_nchar_t[] string literal */
#define mdb_name_cpy strcpy /**< Copy name (#mdb_nchar_t string) */
#endif

/** Filename - string of #mdb_nchar_t[] */
typedef struct MDB_name {
  int mn_len; /**< Length  */
  int mn_alloced; /**< True if #mn_val was malloced */
  mdb_nchar_t* mn_val; /**< Contents */
} MDB_name;

/** Filename suffixes [datafile,lockfile][without,with MDB_NOSUBDIR] */
static const mdb_nchar_t* const mdb_suffixes[2][2] = {
    {MDB_NAME("/data.mdb"), MDB_NAME("")},
    {MDB_NAME("/lock.mdb"), MDB_NAME("-lock")}};

/** Filename suffix lengths (excluding null terminator)
 * [datafile,lockfile][without,with MDB_NOSUBDIR] */
static const size_t mdb_suffix_lens[2][2] = {{9, 0}, {9, 5}};

#define MDB_SUFFLEN 9 /**< Max string length in #mdb_suffixes[] */

/** Set up filename + scratch area for filename suffix, for opening files.
 * It should be freed with #mdb_fname_destroy().
 * On Windows, paths are converted from char *UTF-8 to wchar_t *UTF-16.
 *
 * @param[in] path Pathname for #mdb_env_open().
 * @param[in] envflags Whether a subdir and/or lockfile will be used.
 * @param[out] fname Resulting filename, with room for a suffix if necessary.
 */
static int ESECT
mdb_fname_init(const char* path, unsigned envflags, MDB_name* fname) {
  int no_suffix = F_ISSET(envflags, MDB_NOSUBDIR | MDB_NOLOCK);
  fname->mn_alloced = 0;
#ifdef _WIN32
  return utf8_to_utf16(path, fname, no_suffix ? 0 : MDB_SUFFLEN);
#else
  fname->mn_len = strlen(path);
  if (no_suffix)
    fname->mn_val = (char*)path;
  else if ((fname->mn_val = malloc(fname->mn_len + MDB_SUFFLEN + 1)) != NULL) {
    fname->mn_alloced = 1;
    memcpy(fname->mn_val, path, fname->mn_len + 1);
  } else
    return ENOMEM;
  return MDB_SUCCESS;
#endif
}

/** Destroy \b fname from #mdb_fname_init() */
#define mdb_fname_destroy(fname) \
  do {                           \
    if ((fname).mn_alloced)      \
      free((fname).mn_val);      \
  } while (0)

#ifdef O_CLOEXEC /* POSIX.1-2008: Set FD_CLOEXEC atomically at open() */
#define MDB_CLOEXEC O_CLOEXEC
#else
#define MDB_CLOEXEC 0
#endif

/** File type, access mode etc. for #mdb_fopen() */
enum mdb_fopen_type {
#ifdef _WIN32
  MDB_O_RDONLY,
  MDB_O_RDWR,
  MDB_O_OVERLAPPED,
  MDB_O_META,
  MDB_O_COPY,
  MDB_O_LOCKS
#else
  /* A comment in mdb_fopen() explains some O_* flag choices. */
  MDB_O_RDONLY = O_RDONLY, /**< for RDONLY me_fd */
  MDB_O_RDWR = O_RDWR | O_CREAT, /**< for me_fd */
  MDB_O_META = O_WRONLY | MDB_DSYNC | MDB_CLOEXEC, /**< for me_mfd */
  MDB_O_COPY =
      O_WRONLY | O_CREAT | O_EXCL | MDB_CLOEXEC, /**< for #mdb_env_copy() */
  /** Bitmask for open() flags in enum #mdb_fopen_type.  The other bits
   * distinguish otherwise-equal MDB_O_* constants from each other.
   */
  MDB_O_MASK =
      MDB_O_RDWR | MDB_CLOEXEC | MDB_O_RDONLY | MDB_O_META | MDB_O_COPY,
  MDB_O_LOCKS = MDB_O_RDWR | MDB_CLOEXEC |
      ((MDB_O_MASK + 1) & ~MDB_O_MASK) /**< for me_lfd */
#endif
};

/** Open an LMDB file.
 * @param[in] env	The LMDB environment.
 * @param[in,out] fname	Path from from #mdb_fname_init().  A suffix is
 * appended if necessary to create the filename, without changing mn_len.
 * @param[in] which	Determines file type, access mode, etc.
 * @param[in] mode	The Unix permissions for the file, if we create it.
 * @param[out] res	Resulting file handle.
 * @return 0 on success, non-zero on failure.
 */
static int ESECT mdb_fopen(
    const MDB_env* env,
    MDB_name* fname,
    enum mdb_fopen_type which,
    mdb_mode_t mode,
    HANDLE* res) {
  int rc = MDB_SUCCESS;
  HANDLE fd;
#ifdef _WIN32
  DWORD acc, share, disp, attrs;
#else
  int flags;
#endif

  if (fname->mn_alloced) { /* modifiable copy */
    const mdb_nchar_t* suffix = mdb_suffixes[which == MDB_O_LOCKS][F_ISSET(
        env->me_flags, MDB_NOSUBDIR)];
    size_t suffix_len = mdb_suffix_lens[which == MDB_O_LOCKS]
                                       [F_ISSET(env->me_flags, MDB_NOSUBDIR)] +
        1;
    memcpy(fname->mn_val + fname->mn_len, suffix, suffix_len * sizeof(mdb_nchar_t));
  }

  /* The directory must already exist.  Usually the file need not.
   * MDB_O_META requires the file because we already created it using
   * MDB_O_RDWR.  MDB_O_COPY must not overwrite an existing file.
   *
   * With MDB_O_COPY we do not want the OS to cache the writes, since
   * the source data is already in the OS cache.
   *
   * The lockfile needs FD_CLOEXEC (close file descriptor on exec*())
   * to avoid the flock() issues noted under Caveats in lmdb.h.
   * Also set it for other filehandles which the user cannot get at
   * and close himself, which he may need after fork().  I.e. all but
   * me_fd, which programs do use via mdb_env_get_fd().
   */

#ifdef _WIN32
  acc = GENERIC_READ | GENERIC_WRITE;
  share = FILE_SHARE_READ | FILE_SHARE_WRITE;
  disp = OPEN_ALWAYS;
  attrs = FILE_ATTRIBUTE_NORMAL;
  switch (which) {
    case MDB_O_OVERLAPPED: /* for unbuffered asynchronous writes (write-through
                              mode)*/
      acc = GENERIC_WRITE;
      disp = OPEN_EXISTING;
      attrs = FILE_FLAG_OVERLAPPED | FILE_FLAG_WRITE_THROUGH;
      break;
    case MDB_O_RDONLY: /* read-only datafile */
      acc = GENERIC_READ;
      disp = OPEN_EXISTING;
      break;
    case MDB_O_META: /* for writing metapages */
      acc = GENERIC_WRITE;
      disp = OPEN_EXISTING;
      attrs = FILE_ATTRIBUTE_NORMAL | FILE_FLAG_WRITE_THROUGH;
      break;
    case MDB_O_COPY: /* mdb_env_copy() & co */
      acc = GENERIC_WRITE;
      share = 0;
      disp = CREATE_NEW;
      attrs = FILE_FLAG_NO_BUFFERING | FILE_FLAG_WRITE_THROUGH;
      break;
    default:
      break; /* silence gcc -Wswitch (not all enum values handled) */
  }
  fd = CreateFileW(fname->mn_val, acc, share, NULL, disp, attrs, NULL);
#else
  fd = open(fname->mn_val, which & MDB_O_MASK, mode);
#endif

  if (fd == INVALID_HANDLE_VALUE)
    rc = ErrCode();
#ifndef _WIN32
  else {
    if (which != MDB_O_RDONLY && which != MDB_O_RDWR) {
      /* Set CLOEXEC if we could not pass it to open() */
      if (!MDB_CLOEXEC && (flags = fcntl(fd, F_GETFD)) != -1)
        (void)fcntl(fd, F_SETFD, flags | FD_CLOEXEC);
    }
    if (which == MDB_O_COPY && env->me_psize >= env->me_os_psize) {
      /* This may require buffer alignment.  There is no portable
       * way to ask how much, so we require OS pagesize alignment.
       */
#ifdef F_NOCACHE /* __APPLE__ */
      (void)fcntl(fd, F_NOCACHE, 1);
#elif defined O_DIRECT
      /* open(...O_DIRECT...) would break on filesystems without
       * O_DIRECT support (ITS#7682). Try to set it here instead.
       */
      if ((flags = fcntl(fd, F_GETFL)) != -1)
        (void)fcntl(fd, F_SETFL, flags | O_DIRECT);
#endif
    }
  }
#endif /* !_WIN32 */

  *res = fd;
  return rc;
}

#ifdef BROKEN_FDATASYNC
#include <sys/utsname.h>
#include <sys/vfs.h>
#endif

/** Further setup required for opening an LMDB environment
 */
static int ESECT mdb_env_open2(MDB_env* env, int prev) {
  unsigned int flags = env->me_flags;
  int i, newenv = 0, rc;
  MDB_meta meta;

#ifdef _WIN32
  /* See if we should use QueryLimited */
  rc = GetVersion();
  if ((rc & 0xff) > 5)
    env->me_pidquery = MDB_PROCESS_QUERY_LIMITED_INFORMATION;
  else
    env->me_pidquery = PROCESS_QUERY_INFORMATION;
  /* Grab functions we need from NTDLL */
  if (!NtCreateSection) {
    HMODULE h = GetModuleHandleW(L"NTDLL.DLL");
    if (!h)
      return MDB_PROBLEM;
    NtClose = (NtCloseFunc*)GetProcAddress(h, "NtClose");
    if (!NtClose)
      return MDB_PROBLEM;
    NtMapViewOfSection =
        (NtMapViewOfSectionFunc*)GetProcAddress(h, "NtMapViewOfSection");
    if (!NtMapViewOfSection)
      return MDB_PROBLEM;
    NtCreateSection =
        (NtCreateSectionFunc*)GetProcAddress(h, "NtCreateSection");
    if (!NtCreateSection)
      return MDB_PROBLEM;
  }
  env->ovs = 0;
#endif /* _WIN32 */

#ifdef BROKEN_FDATASYNC
  /* ext3/ext4 fdatasync is broken on some older Linux kernels.
   * https://lkml.org/lkml/2012/9/3/83
   * Kernels after 3.6-rc6 are known good.
   * https://lkml.org/lkml/2012/9/10/556
   * See if the DB is on ext3/ext4, then check for new enough kernel
   * Kernels 2.6.32.60, 2.6.34.15, 3.2.30, and 3.5.4 are also known
   * to be patched.
   */
  {
    struct statfs st;
    fstatfs(env->me_fd, &st);
    while (st.f_type == 0xEF53) {
      struct utsname uts;
      int i;
      uname(&uts);
      if (uts.release[0] < '3') {
        if (!strncmp(uts.release, "2.6.32.", 7)) {
          i = atoi(uts.release + 7);
          if (i >= 60)
            break; /* 2.6.32.60 and newer is OK */
        } else if (!strncmp(uts.release, "2.6.34.", 7)) {
          i = atoi(uts.release + 7);
          if (i >= 15)
            break; /* 2.6.34.15 and newer is OK */
        }
      } else if (uts.release[0] == '3') {
        i = atoi(uts.release + 2);
        if (i > 5)
          break; /* 3.6 and newer is OK */
        if (i == 5) {
          i = atoi(uts.release + 4);
          if (i >= 4)
            break; /* 3.5.4 and newer is OK */
        } else if (i == 2) {
          i = atoi(uts.release + 4);
          if (i >= 30)
            break; /* 3.2.30 and newer is OK */
        }
      } else { /* 4.x and newer is OK */
        break;
      }
      env->me_flags |= MDB_FSYNCONLY;
      break;
    }
  }
#endif

  if ((i = mdb_env_read_header(env, prev, &meta)) != 0) {
    if (i != ENOENT)
      return i;
    DPUTS("new mdbenv");
    newenv = 1;
    env->me_psize = env->me_os_psize;
    if (env->me_psize > MAX_PAGESIZE)
      env->me_psize = MAX_PAGESIZE;
    memset(&meta, 0, sizeof(meta));
    mdb_env_init_meta0(env, &meta);
    meta.mm_mapsize = DEFAULT_MAPSIZE;
  } else {
    env->me_psize = meta.mm_psize;
  }

  /* Was a mapsize configured? */
  if (!env->me_mapsize) {
    env->me_mapsize = meta.mm_mapsize;
  }
  {
    /* Make sure mapsize >= committed data size.  Even when using
     * mm_mapsize, which could be broken in old files (ITS#7789).
     */
    mdb_size_t minsize = (meta.mm_last_pg + 1) * meta.mm_psize;
    if (env->me_mapsize < minsize)
      env->me_mapsize = minsize;
  }
  meta.mm_mapsize = env->me_mapsize;

  if (newenv && !(flags & MDB_FIXEDMAP)) {
    /* mdb_env_map() may grow the datafile.  Write the metapages
     * first, so the file will be valid if initialization fails.
     * Except with FIXEDMAP, since we do not yet know mm_address.
     * We could fill in mm_address later, but then a different
     * program might end up doing that - one with a memory layout
     * and map address which does not suit the main program.
     */
    rc = mdb_env_init_meta(env, &meta);
    if (rc)
      return rc;
    newenv = 0;
  }
#ifdef _WIN32
  /* For FIXEDMAP, make sure the file is non-empty before we attempt to map it
   */
  if (newenv) {
    char dummy = 0;
    DWORD len;
    rc = WriteFile(env->me_fd, &dummy, 1, &len, NULL);
    if (!rc) {
      rc = ErrCode();
      return rc;
    }
  }
#endif

  rc = mdb_env_map(env, (flags & MDB_FIXEDMAP) ? meta.mm_address : NULL);
  if (rc)
    return rc;

  if (newenv) {
    if (flags & MDB_FIXEDMAP)
      meta.mm_address = env->me_map;
    i = mdb_env_init_meta(env, &meta);
    if (i != MDB_SUCCESS) {
      return i;
    }
  }

  env->me_maxfree_1pg = (env->me_psize - PAGEHDRSZ) / sizeof(pgno_t) - 1;
  env->me_nodemax =
      (((env->me_psize - PAGEHDRSZ) / MDB_MINKEYS) & -2) - sizeof(indx_t);
#if !(MDB_MAXKEYSIZE)
  env->me_maxkey = env->me_nodemax - (NODESIZE + sizeof(MDB_db));
#endif
  env->me_maxpg = env->me_mapsize / env->me_psize;

  if (prev && env->me_txns)
    env->me_txns->mti_txnid = meta.mm_txnid;

#if MDB_DEBUG
  {
    MDB_meta* meta = mdb_env_pick_meta(env);
    MDB_db* db = &meta->mm_dbs[MAIN_DBI];

    DPRINTF(
        ("opened database version %u, pagesize %u",
         meta->mm_version,
         env->me_psize));
    DPRINTF(("using meta page %d", (int)(meta->mm_txnid & 1)));
    DPRINTF(("depth: %u", db->md_depth));
    DPRINTF(("entries: %" Yu, db->md_entries));
    DPRINTF(("branch pages: %" Yu, db->md_branch_pages));
    DPRINTF(("leaf pages: %" Yu, db->md_leaf_pages));
    DPRINTF(("overflow pages: %" Yu, db->md_overflow_pages));
    DPRINTF(("root: %" Yu, db->md_root));
  }
#endif

  return MDB_SUCCESS;
}

/** Release a reader thread's slot in the reader lock table.
 *	This function is called automatically when a thread exits.
 * @param[in] ptr This points to the slot in the reader lock table.
 */
static void mdb_env_reader_dest(void* ptr) {
  MDB_reader* reader = ptr;

#ifndef _WIN32
  if (reader->mr_pid == getpid()) /* catch pthread_exit() in child process */
#endif
    /* We omit the mutex, so do this atomically (i.e. skip mr_txnid) */
    reader->mr_pid = 0;
}

#ifdef _WIN32
/** Junk for arranging thread-specific callbacks on Windows. This is
 *	necessarily platform and compiler-specific. Windows supports up
 *	to 1088 keys. Let's assume nobody opens more than 64 environments
 *	in a single process, for now. They can override this if needed.
 */
#ifndef MAX_TLS_KEYS
#define MAX_TLS_KEYS 64
#endif
static pthread_key_t mdb_tls_keys[MAX_TLS_KEYS];
static int mdb_tls_nkeys;

static void NTAPI mdb_tls_callback(PVOID module, DWORD reason, PVOID ptr) {
  int i;
  switch (reason) {
    case DLL_PROCESS_ATTACH:
      break;
    case DLL_THREAD_ATTACH:
      break;
    case DLL_THREAD_DETACH:
      for (i = 0; i < mdb_tls_nkeys; i++) {
        MDB_reader* r = pthread_getspecific(mdb_tls_keys[i]);
        if (r) {
          mdb_env_reader_dest(r);
        }
      }
      break;
    case DLL_PROCESS_DETACH:
      break;
  }
}
#ifdef __GNUC__
#ifdef _WIN64
const PIMAGE_TLS_CALLBACK mdb_tls_cbp __attribute__((section(".CRT$XLB"))) =
    mdb_tls_callback;
#else
PIMAGE_TLS_CALLBACK mdb_tls_cbp __attribute__((section(".CRT$XLB"))) =
    mdb_tls_callback;
#endif
#else
#ifdef _WIN64
/* Force some symbol references.
 *	_tls_used forces the linker to create the TLS directory if not already
 * done mdb_tls_cbp prevents whole-program-optimizer from dropping the symbol.
 */
#pragma comment(linker, "/INCLUDE:_tls_used")
#pragma comment(linker, "/INCLUDE:mdb_tls_cbp")
#pragma const_seg(".CRT$XLB")
extern const PIMAGE_TLS_CALLBACK mdb_tls_cbp;
const PIMAGE_TLS_CALLBACK mdb_tls_cbp = mdb_tls_callback;
#pragma const_seg()
#else /* _WIN32 */
#pragma comment(linker, "/INCLUDE:__tls_used")
#pragma comment(linker, "/INCLUDE:_mdb_tls_cbp")
#pragma data_seg(".CRT$XLB")
PIMAGE_TLS_CALLBACK mdb_tls_cbp = mdb_tls_callback;
#pragma data_seg()
#endif /* WIN 32/64 */
#endif /* !__GNUC__ */
#endif

/** Downgrade the exclusive lock on the region back to shared */
static int ESECT mdb_env_share_locks(MDB_env* env, int* excl) {
  int rc = 0;
  MDB_meta* meta = mdb_env_pick_meta(env);

  env->me_txns->mti_txnid = meta->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));
    if (!LockFileEx(env->me_lfd, 0, 0, 1, 0, &ov)) {
      rc = ErrCode();
    } else {
      UnlockFile(env->me_lfd, 0, 0, 1, 0);
      *excl = 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;
    while ((rc = fcntl(env->me_lfd, F_SETLK, &lock_info)) &&
           (rc = ErrCode()) == EINTR)
      ;
    *excl = rc ? -1 : 0; /* error may mean we lost the lock */
  }
#endif

  return rc;
}

/** Try to get exclusive lock, otherwise shared.
 *	Maintain *excl = -1: no/unknown lock, 0: shared, 1: exclusive.
 */
static int ESECT mdb_env_excl_lock(MDB_env* env, int* excl) {
  int rc = 0;
#ifdef _WIN32
  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)) {
      *excl = 0;
    } else {
      rc = ErrCode();
    }
  }
#else
  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;
  while ((rc = fcntl(env->me_lfd, F_SETLK, &lock_info)) &&
         (rc = ErrCode()) == EINTR)
    ;
  if (!rc) {
    *excl = 1;
  } else
#ifndef MDB_USE_POSIX_MUTEX
      if (*excl < 0) /* always true when MDB_USE_POSIX_MUTEX */
#endif
  {
    lock_info.l_type = F_RDLCK;
    while ((rc = fcntl(env->me_lfd, F_SETLKW, &lock_info)) &&
           (rc = ErrCode()) == EINTR)
      ;
    if (rc == 0)
      *excl = 0;
  }
#endif
  return rc;
}

#ifdef MDB_USE_HASH
/*
 * hash_64 - 64 bit Fowler/Noll/Vo-0 FNV-1a hash code
 *
 * @(#) $Revision: 5.1 $
 * @(#) $Id: hash_64a.c,v 5.1 2009/06/30 09:01:38 chongo Exp $
 * @(#) $Source: /usr/local/src/cmd/fnv/RCS/hash_64a.c,v $
 *
 *	  http://www.isthe.com/chongo/tech/comp/fnv/index.html
 *
 ***
 *
 * Please do not copyright this code.  This code is in the public domain.
 *
 * LANDON CURT NOLL DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE,
 * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO
 * EVENT SHALL LANDON CURT NOLL BE LIABLE FOR ANY SPECIAL, 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.
 *
 * By:
 *	chongo <Landon Curt Noll> /\oo/\
 *	  http://www.isthe.com/chongo/
 *
 * Share and Enjoy!	:-)
 */

/** perform a 64 bit Fowler/Noll/Vo FNV-1a hash on a buffer
 * @param[in] val	value to hash
 * @param[in] len	length of value
 * @return 64 bit hash
 */
static mdb_hash_t mdb_hash(const void* val, size_t len) {
  const unsigned char *s = (const unsigned char*)val, *end = s + len;
  mdb_hash_t hval = 0xcbf29ce484222325ULL;
  /*
   * FNV-1a hash each octet of the buffer
   */
  while (s < end) {
    hval = (hval ^ *s++) * 0x100000001b3ULL;
  }
  /* return our new hash value */
  return hval;
}

/** Hash the string and output the encoded hash.
 * This uses modified RFC1924 Ascii85 encoding to accommodate systems with
 * very short name limits. We don't care about the encoding being reversible,
 * we just want to preserve as many bits of the input as possible in a
 * small printable string.
 * @param[in] str string to hash
 * @param[out] encbuf an array of 11 chars to hold the hash
 */
static const char mdb_a85[] =
    "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz!#$%&()*+-;<=>?@^_`{|}~";

static void ESECT mdb_pack85(unsigned long long l, char* out) {
  int i;

  for (i = 0; i < 10 && l; i++) {
    *out++ = mdb_a85[l % 85];
    l /= 85;
  }
  *out = '\0';
}

/** Init #MDB_env.me_mutexname[] except the char which #MUTEXNAME() will set.
 *	Changes to this code must be reflected in #MDB_LOCK_FORMAT.
 */
static void ESECT mdb_env_mname_init(MDB_env* env) {
  char* nm = env->me_mutexname;
  strcpy(nm, MUTEXNAME_PREFIX);
  mdb_pack85(env->me_txns->mti_mutexid, nm + sizeof(MUTEXNAME_PREFIX));
}

/** Return env->me_mutexname after filling in ch ('r'/'w') for convenience */
#define MUTEXNAME(env, ch)                                           \
  ((void)((env)->me_mutexname[sizeof(MUTEXNAME_PREFIX) - 1] = (ch)), \
   (env)->me_mutexname)

#endif

/** Open and/or initialize the lock region for the environment.
 * @param[in] env The LMDB environment.
 * @param[in] fname Filename + scratch area, from #mdb_fname_init().
 * @param[in] mode The Unix permissions for the file, if we create it.
 * @param[in,out] excl In -1, out lock type: -1 none, 0 shared, 1 exclusive
 * @return 0 on success, non-zero on failure.
 */
static int ESECT
mdb_env_setup_locks(MDB_env* env, MDB_name* fname, int mode, int* excl) {
#ifdef _WIN32
#define MDB_ERRCODE_ROFS ERROR_WRITE_PROTECT
#else
#define MDB_ERRCODE_ROFS EROFS
#endif
#ifdef MDB_USE_SYSV_SEM
  int semid;
  union semun semu;
#endif
  int rc;
  MDB_OFF_T size, rsize;

  rc = mdb_fopen(env, fname, MDB_O_LOCKS, mode, &env->me_lfd);
  if (rc) {
    /* Omit lockfile if read-only env on read-only filesystem */
    if (rc == MDB_ERRCODE_ROFS && (env->me_flags & MDB_RDONLY)) {
      return MDB_SUCCESS;
    }
    goto fail;
  }

  if (!(env->me_flags & MDB_NOTLS)) {
    rc = pthread_key_create(&env->me_txkey, mdb_env_reader_dest);
    if (rc)
      goto fail;
    env->me_flags |= MDB_ENV_TXKEY;
#ifdef _WIN32
    /* Windows TLS callbacks need help finding their TLS info. */
    if (mdb_tls_nkeys >= MAX_TLS_KEYS) {
      rc = MDB_TLS_FULL;
      goto fail;
    }
    mdb_tls_keys[mdb_tls_nkeys++] = env->me_txkey;
#endif
  }

  /* Try to get exclusive lock. If we succeed, then
   * nobody is using the lock region and we should initialize it.
   */
  if ((rc = mdb_env_excl_lock(env, excl)))
    goto fail;

#ifdef _WIN32
  size = GetFileSize(env->me_lfd, NULL);
#else
  size = lseek(env->me_lfd, 0, SEEK_END);
  if (size == -1)
    goto fail_errno;
#endif
  rsize = (env->me_maxreaders - 1) * sizeof(MDB_reader) + sizeof(MDB_txninfo);
  if (size < rsize && *excl > 0) {
#ifdef _WIN32
    if (SetFilePointer(env->me_lfd, rsize, NULL, FILE_BEGIN) != (DWORD)rsize ||
        !SetEndOfFile(env->me_lfd))
      goto fail_errno;
#else
    if (ftruncate(env->me_lfd, rsize) != 0)
      goto fail_errno;
#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)
      goto fail_errno;
    env->me_txns = MapViewOfFileEx(mh, FILE_MAP_WRITE, 0, 0, rsize, NULL);
    CloseHandle(mh);
    if (!env->me_txns)
      goto fail_errno;
#else
    void* m =
        mmap(NULL, rsize, PROT_READ | PROT_WRITE, MAP_SHARED, env->me_lfd, 0);
    if (m == MAP_FAILED)
      goto fail_errno;
    env->me_txns = m;
#endif
  }
  if (*excl > 0) {
#ifdef _WIN32
    BY_HANDLE_FILE_INFORMATION stbuf;
    struct {
      DWORD volume;
      DWORD nhigh;
      DWORD nlow;
    } idbuf;

    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;
    }
    if (!GetFileInformationByHandle(env->me_lfd, &stbuf))
      goto fail_errno;
    idbuf.volume = stbuf.dwVolumeSerialNumber;
    idbuf.nhigh = stbuf.nFileIndexHigh;
    idbuf.nlow = stbuf.nFileIndexLow;
    env->me_txns->mti_mutexid = mdb_hash(&idbuf, sizeof(idbuf));
    mdb_env_mname_init(env);
    env->me_rmutex = CreateMutexA(&mdb_all_sa, FALSE, MUTEXNAME(env, 'r'));
    if (!env->me_rmutex)
      goto fail_errno;
    env->me_wmutex = CreateMutexA(&mdb_all_sa, FALSE, MUTEXNAME(env, 'w'));
    if (!env->me_wmutex)
      goto fail_errno;
#elif defined(MDB_USE_POSIX_SEM)
    struct stat stbuf;
    struct {
      dev_t dev;
      ino_t ino;
    } idbuf;

#if defined(__NetBSD__)
#define MDB_SHORT_SEMNAMES 1 /* limited to 14 chars */
#endif
    if (fstat(env->me_lfd, &stbuf))
      goto fail_errno;
    memset(&idbuf, 0, sizeof(idbuf));
    idbuf.dev = stbuf.st_dev;
    idbuf.ino = stbuf.st_ino;
    env->me_txns->mti_mutexid = mdb_hash(&idbuf, sizeof(idbuf))
#ifdef MDB_SHORT_SEMNAMES
        /* Max 9 base85-digits.  We truncate here instead of in
         * mdb_env_mname_init() to keep the latter portable.
         */
        % ((mdb_hash_t)85 * 85 * 85 * 85 * 85 * 85 * 85 * 85 * 85)
#endif
        ;
    mdb_env_mname_init(env);
    /* Clean up after a previous run, if needed:  Try to
     * remove both semaphores before doing anything else.
     */
    sem_unlink(MUTEXNAME(env, 'r'));
    sem_unlink(MUTEXNAME(env, 'w'));
    env->me_rmutex = sem_open(MUTEXNAME(env, 'r'), O_CREAT | O_EXCL, mode, 1);
    if (env->me_rmutex == SEM_FAILED)
      goto fail_errno;
    env->me_wmutex = sem_open(MUTEXNAME(env, 'w'), O_CREAT | O_EXCL, mode, 1);
    if (env->me_wmutex == SEM_FAILED)
      goto fail_errno;
#elif defined(MDB_USE_SYSV_SEM)
      unsigned short vals[2] = {1, 1};
      key_t key = ftok(fname->mn_val, 'M'); /* fname is lockfile path now */
      if (key == -1)
        goto fail_errno;
      semid = semget(key, 2, (mode & 0777) | IPC_CREAT);
      if (semid < 0)
        goto fail_errno;
      semu.array = vals;
      if (semctl(semid, 0, SETALL, semu) < 0)
        goto fail_errno;
      env->me_txns->mti_semid = semid;
      env->me_txns->mti_rlocked = 0;
      env->me_txns->mti_wlocked = 0;
#else /* MDB_USE_POSIX_MUTEX: */
      pthread_mutexattr_t mattr;

      /* Solaris needs this before initing a robust mutex.  Otherwise
       * it may skip the init and return EBUSY "seems someone already
       * inited" or EINVAL "it was inited differently".
       */
      memset(env->me_txns->mti_rmutex, 0, sizeof(*env->me_txns->mti_rmutex));
      memset(env->me_txns->mti_wmutex, 0, sizeof(*env->me_txns->mti_wmutex));

      if ((rc = pthread_mutexattr_init(&mattr)) != 0)
        goto fail;
      rc = pthread_mutexattr_setpshared(&mattr, PTHREAD_PROCESS_SHARED);
#ifdef MDB_ROBUST_SUPPORTED
      if (!rc)
        rc = pthread_mutexattr_setrobust(&mattr, PTHREAD_MUTEX_ROBUST);
#endif
      if (!rc)
        rc = pthread_mutex_init(env->me_txns->mti_rmutex, &mattr);
      if (!rc)
        rc = pthread_mutex_init(env->me_txns->mti_wmutex, &mattr);
      pthread_mutexattr_destroy(&mattr);
      if (rc)
        goto fail;
#endif /* _WIN32 || ... */

    env->me_txns->mti_magic = MDB_MAGIC;
    env->me_txns->mti_format = MDB_LOCK_FORMAT;
    env->me_txns->mti_txnid = 0;
    env->me_txns->mti_numreaders = 0;

  } else {
#ifdef MDB_USE_SYSV_SEM
    struct semid_ds buf;
#endif
    if (env->me_txns->mti_magic != MDB_MAGIC) {
      DPUTS("lock region has invalid magic");
      rc = MDB_INVALID;
      goto fail;
    }
    if (env->me_txns->mti_format != MDB_LOCK_FORMAT) {
      DPRINTF(
          ("lock region has format+version 0x%x, expected 0x%x",
           env->me_txns->mti_format,
           MDB_LOCK_FORMAT));
      rc = MDB_VERSION_MISMATCH;
      goto fail;
    }
    rc = ErrCode();
    if (rc && rc != EACCES && rc != EAGAIN) {
      goto fail;
    }
#ifdef _WIN32
    mdb_env_mname_init(env);
    env->me_rmutex = OpenMutexA(SYNCHRONIZE, FALSE, MUTEXNAME(env, 'r'));
    if (!env->me_rmutex)
      goto fail_errno;
    env->me_wmutex = OpenMutexA(SYNCHRONIZE, FALSE, MUTEXNAME(env, 'w'));
    if (!env->me_wmutex)
      goto fail_errno;
#elif defined(MDB_USE_POSIX_SEM)
    mdb_env_mname_init(env);
    env->me_rmutex = sem_open(MUTEXNAME(env, 'r'), 0);
    if (env->me_rmutex == SEM_FAILED)
      goto fail_errno;
    env->me_wmutex = sem_open(MUTEXNAME(env, 'w'), 0);
    if (env->me_wmutex == SEM_FAILED)
      goto fail_errno;
#elif defined(MDB_USE_SYSV_SEM)
      semid = env->me_txns->mti_semid;
      semu.buf = &buf;
      /* check for read access */
      if (semctl(semid, 0, IPC_STAT, semu) < 0)
        goto fail_errno;
      /* check for write access */
      if (semctl(semid, 0, IPC_SET, semu) < 0)
        goto fail_errno;
#endif
  }
#ifdef MDB_USE_SYSV_SEM
  env->me_rmutex->semid = semid;
  env->me_wmutex->semid = semid;
  env->me_rmutex->semnum = 0;
  env->me_wmutex->semnum = 1;
  env->me_rmutex->locked = &env->me_txns->mti_rlocked;
  env->me_wmutex->locked = &env->me_txns->mti_wlocked;
#endif

  return MDB_SUCCESS;

fail_errno:
  rc = ErrCode();
fail:
  return rc;
}

/** 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 | MDB_NOMETASYNC | MDB_MAPASYNC | MDB_NOMEMINIT)
#define CHANGELESS                                                       \
  (MDB_FIXEDMAP | MDB_NOSUBDIR | MDB_RDONLY | MDB_WRITEMAP | MDB_NOTLS | \
   MDB_NOLOCK | MDB_NORDAHEAD | MDB_PREVSNAPSHOT)

#if VALID_FLAGS & PERSISTENT_FLAGS & (CHANGEABLE | CHANGELESS)
#error "Persistent DB flags & env flags overlap, but both go in mm_flags"
#endif

int ESECT mdb_env_open(
    MDB_env* env,
    const char* path,
    unsigned int flags,
    mdb_mode_t mode) {
  int rc, excl = -1;
  MDB_name fname;

  if (env->me_fd != INVALID_HANDLE_VALUE ||
      (flags & ~(CHANGEABLE | CHANGELESS)))
    return EINVAL;

#ifdef MDB_VL32
  if (flags & MDB_WRITEMAP) {
    /* silently ignore WRITEMAP in 32 bit mode */
    flags ^= MDB_WRITEMAP;
  }
  if (flags & MDB_FIXEDMAP) {
    /* cannot support FIXEDMAP */
    return EINVAL;
  }
#endif
  flags |= env->me_flags;

  rc = mdb_fname_init(path, flags, &fname);
  if (rc)
    return rc;

#ifdef MDB_VL32
#ifdef _WIN32
  env->me_rpmutex = CreateMutex(NULL, FALSE, NULL);
  if (!env->me_rpmutex) {
    rc = ErrCode();
    goto leave;
  }
#else
  rc = pthread_mutex_init(&env->me_rpmutex, NULL);
  if (rc)
    goto leave;
#endif
#endif
  flags |= MDB_ENV_ACTIVE; /* tell mdb_env_close0() to clean up */

  if (flags & MDB_RDONLY) {
    /* silently ignore WRITEMAP when we're only getting read access */
    flags &= ~MDB_WRITEMAP;
  } else {
    if (!((env->me_free_pgs = mdb_midl_alloc(MDB_IDL_UM_MAX)) &&
          (env->me_dirty_list = calloc(MDB_IDL_UM_SIZE, sizeof(MDB_ID2)))))
      rc = ENOMEM;
  }

  env->me_flags = flags;
  if (rc)
    goto leave;

#ifdef MDB_VL32
  {
    env->me_rpages = malloc(MDB_ERPAGE_SIZE * sizeof(MDB_ID3));
    if (!env->me_rpages) {
      rc = ENOMEM;
      goto leave;
    }
    env->me_rpages[0].mid = 0;
    env->me_rpcheck = MDB_ERPAGE_SIZE / 2;
  }
#endif

  env->me_path = strdup(path);
  env->me_dbxs = calloc(env->me_maxdbs, sizeof(MDB_dbx));
  env->me_dbflags = calloc(env->me_maxdbs, sizeof(uint16_t));
  env->me_dbiseqs = calloc(env->me_maxdbs, sizeof(unsigned int));
  if (!(env->me_dbxs && env->me_path && env->me_dbflags && env->me_dbiseqs)) {
    rc = ENOMEM;
    goto leave;
  }
  env->me_dbxs[FREE_DBI].md_cmp = mdb_cmp_long; /* aligned MDB_INTEGERKEY */

  /* For RDONLY, get lockfile after we know datafile exists */
  if (!(flags & (MDB_RDONLY | MDB_NOLOCK))) {
    rc = mdb_env_setup_locks(env, &fname, mode, &excl);
    if (rc)
      goto leave;
    if ((flags & MDB_PREVSNAPSHOT) && !excl) {
      rc = EAGAIN;
      goto leave;
    }
  }

  rc = mdb_fopen(
      env,
      &fname,
      (flags & MDB_RDONLY) ? MDB_O_RDONLY : MDB_O_RDWR,
      mode,
      &env->me_fd);
  if (rc)
    goto leave;
#ifdef _WIN32
  rc = mdb_fopen(env, &fname, MDB_O_OVERLAPPED, mode, &env->me_ovfd);
  if (rc)
    goto leave;
#endif

  if ((flags & (MDB_RDONLY | MDB_NOLOCK)) == MDB_RDONLY) {
    rc = mdb_env_setup_locks(env, &fname, mode, &excl);
    if (rc)
      goto leave;
  }

  if ((rc = mdb_env_open2(env, flags & MDB_PREVSNAPSHOT)) == MDB_SUCCESS) {
    /* Synchronous fd for meta writes. Needed even with
     * MDB_NOSYNC/MDB_NOMETASYNC, in case these get reset.
     */
    if (!(flags & (MDB_RDONLY | MDB_WRITEMAP))) {
      rc = mdb_fopen(env, &fname, MDB_O_META, mode, &env->me_mfd);
      if (rc)
        goto leave;
    }
    DPRINTF(("opened dbenv %p", (void*)env));
    if (excl > 0 && !(flags & MDB_PREVSNAPSHOT)) {
      rc = mdb_env_share_locks(env, &excl);
      if (rc)
        goto leave;
    }
    if (!(flags & MDB_RDONLY)) {
      MDB_txn* txn;
      int tsize = sizeof(MDB_txn),
          size = tsize +
          env->me_maxdbs *
              (sizeof(MDB_db) + sizeof(MDB_cursor*) + sizeof(unsigned int) + 1);
      if ((env->me_pbuf = calloc(1, env->me_psize)) &&
          (txn = calloc(1, size))) {
        txn->mt_dbs = (MDB_db*)((char*)txn + tsize);
        txn->mt_cursors = (MDB_cursor**)(txn->mt_dbs + env->me_maxdbs);
        txn->mt_dbiseqs = (unsigned int*)(txn->mt_cursors + env->me_maxdbs);
        txn->mt_dbflags = (unsigned char*)(txn->mt_dbiseqs + env->me_maxdbs);
        txn->mt_env = env;
#ifdef MDB_VL32
        txn->mt_rpages = malloc(MDB_TRPAGE_SIZE * sizeof(MDB_ID3));
        if (!txn->mt_rpages) {
          free(txn);
          rc = ENOMEM;
          goto leave;
        }
        txn->mt_rpages[0].mid = 0;
        txn->mt_rpcheck = MDB_TRPAGE_SIZE / 2;
#endif
        txn->mt_dbxs = env->me_dbxs;
        txn->mt_flags = MDB_TXN_FINISHED;
        env->me_txn0 = txn;
      } else {
        rc = ENOMEM;
      }
    }
  }

leave:
  MDB_TRACE(
      ("%p, %s, %u, %04o", env, path, flags & (CHANGEABLE | CHANGELESS), mode));
  if (rc) {
    mdb_env_close0(env, excl);
  }
  mdb_fname_destroy(fname);
  return rc;
}

/** Destroy resources from mdb_env_open(), clear our readers & DBIs */
static void ESECT mdb_env_close0(MDB_env* env, int excl) {
  int i;

  if (!(env->me_flags & MDB_ENV_ACTIVE))
    return;

  /* Doing this here since me_dbxs may not exist during mdb_env_close */
  if (env->me_dbxs) {
    for (i = env->me_maxdbs; --i >= CORE_DBS;)
      free(env->me_dbxs[i].md_name.mv_data);
    free(env->me_dbxs);
  }

  free(env->me_pbuf);
  free(env->me_dbiseqs);
  free(env->me_dbflags);
  free(env->me_path);
  free(env->me_dirty_list);
#ifdef MDB_VL32
  if (env->me_txn0 && env->me_txn0->mt_rpages)
    free(env->me_txn0->mt_rpages);
  if (env->me_rpages) {
    MDB_ID3L el = env->me_rpages;
    unsigned int x;
    for (x = 1; x <= el[0].mid; x++)
      munmap(el[x].mptr, el[x].mcnt * env->me_psize);
    free(el);
  }
#endif
  free(env->me_txn0);
  mdb_midl_free(env->me_free_pgs);

  if (env->me_flags & MDB_ENV_TXKEY) {
    pthread_key_delete(env->me_txkey);
#ifdef _WIN32
    /* Delete our key from the global list */
    for (i = 0; i < mdb_tls_nkeys; i++)
      if (mdb_tls_keys[i] == env->me_txkey) {
        mdb_tls_keys[i] = mdb_tls_keys[mdb_tls_nkeys - 1];
        mdb_tls_nkeys--;
        break;
      }
#endif
  }

  if (env->me_map) {
#ifdef MDB_VL32
    munmap(env->me_map, NUM_METAS * env->me_psize);
#else
    munmap(env->me_map, env->me_mapsize);
#endif
  }
  if (env->me_mfd != INVALID_HANDLE_VALUE)
    (void)close(env->me_mfd);
#ifdef _WIN32
  if (env->ovs > 0) {
    for (i = 0; i < env->ovs; i++) {
      CloseHandle(env->ov[i].hEvent);
    }
    free(env->ov);
  }
  if (env->me_ovfd != INVALID_HANDLE_VALUE)
    (void)close(env->me_ovfd);
#endif
  if (env->me_fd != INVALID_HANDLE_VALUE)
    (void)close(env->me_fd);
  if (env->me_txns) {
    MDB_PID_T pid = getpid();
    /* Clearing readers is done in this function because
     * me_txkey with its destructor must be disabled first.
     *
     * We skip the the reader mutex, so we touch only
     * data owned by this process (me_close_readers and
     * our readers), and clear each reader atomically.
     */
    for (i = env->me_close_readers; --i >= 0;)
      if (env->me_txns->mti_readers[i].mr_pid == pid)
        env->me_txns->mti_readers[i].mr_pid = 0;
#ifdef _WIN32
    if (env->me_rmutex) {
      CloseHandle(env->me_rmutex);
      if (env->me_wmutex)
        CloseHandle(env->me_wmutex);
    }
    /* Windows automatically destroys the mutexes when
     * the last handle closes.
     */
#elif defined(MDB_USE_POSIX_SEM)
    if (env->me_rmutex != SEM_FAILED) {
      sem_close(env->me_rmutex);
      if (env->me_wmutex != SEM_FAILED)
        sem_close(env->me_wmutex);
      /* If we have the filelock:  If we are the
       * only remaining user, clean up semaphores.
       */
      if (excl == 0)
        mdb_env_excl_lock(env, &excl);
      if (excl > 0) {
        sem_unlink(MUTEXNAME(env, 'r'));
        sem_unlink(MUTEXNAME(env, 'w'));
      }
    }
#elif defined(MDB_USE_SYSV_SEM)
      if (env->me_rmutex->semid != -1) {
        /* If we have the filelock:  If we are the
         * only remaining user, clean up semaphores.
         */
        if (excl == 0)
          mdb_env_excl_lock(env, &excl);
        if (excl > 0)
          semctl(env->me_rmutex->semid, 0, IPC_RMID);
      }
#endif
    munmap(
        (void*)env->me_txns,
        (env->me_maxreaders - 1) * sizeof(MDB_reader) + sizeof(MDB_txninfo));
  }
  if (env->me_lfd != INVALID_HANDLE_VALUE) {
#ifdef _WIN32
    if (excl >= 0) {
      /* Unlock the lockfile.  Windows would have unlocked it
       * after closing anyway, but not necessarily at once.
       */
      UnlockFile(env->me_lfd, 0, 0, 1, 0);
    }
#endif
    (void)close(env->me_lfd);
  }
#ifdef MDB_VL32
#ifdef _WIN32
  if (env->me_fmh)
    CloseHandle(env->me_fmh);
  if (env->me_rpmutex)
    CloseHandle(env->me_rpmutex);
#else
  pthread_mutex_destroy(&env->me_rpmutex);
#endif
#endif

  env->me_flags &= ~(MDB_ENV_ACTIVE | MDB_ENV_TXKEY);
}

void ESECT mdb_env_close(MDB_env* env) {
  MDB_page* dp;

  if (env == NULL)
    return;

  MDB_TRACE(("%p", env));
  VGMEMP_DESTROY(env);
  while ((dp = env->me_dpages) != NULL) {
    VGMEMP_DEFINED(&dp->mp_next, sizeof(dp->mp_next));
    env->me_dpages = dp->mp_next;
    free(dp);
  }

  mdb_env_close0(env, 0);
  free(env);
}

/** Compare two items pointing at aligned #mdb_size_t's */
static int mdb_cmp_long(const MDB_val* a, const MDB_val* b) {
  return (*(mdb_size_t*)a->mv_data < *(mdb_size_t*)b->mv_data)
      ? -1
      : *(mdb_size_t*)a->mv_data > *(mdb_size_t*)b->mv_data;
}

/** Compare two items pointing at aligned unsigned int's.
 *
 *	This is also set as #MDB_INTEGERDUP|#MDB_DUPFIXED's #MDB_dbx.%md_dcmp,
 *	but #mdb_cmp_clong() is called instead if the data type is #mdb_size_t.
 */
static int mdb_cmp_int(const MDB_val* a, const MDB_val* b) {
  return (*(unsigned int*)a->mv_data < *(unsigned int*)b->mv_data)
      ? -1
      : *(unsigned int*)a->mv_data > *(unsigned int*)b->mv_data;
}

/** Compare two items pointing at unsigned ints of unknown alignment.
 *	Nodes and keys are guaranteed to be 2-byte aligned.
 */
static int mdb_cmp_cint(const MDB_val* a, const MDB_val* b) {
#if BYTE_ORDER == LITTLE_ENDIAN
  unsigned short *u, *c;
  int x;

  u = (unsigned short*)((char*)a->mv_data + a->mv_size);
  c = (unsigned short*)((char*)b->mv_data + a->mv_size);
  do {
    x = *--u - *--c;
  } while (!x && u > (unsigned short*)a->mv_data);
  return x;
#else
  unsigned short *u, *c, *end;
  int x;

  end = (unsigned short*)((char*)a->mv_data + a->mv_size);
  u = (unsigned short*)a->mv_data;
  c = (unsigned short*)b->mv_data;
  do {
    x = *u++ - *c++;
  } while (!x && u < end);
  return x;
#endif
}

/** Compare two items lexically */
static int mdb_cmp_memn(const MDB_val* a, const MDB_val* b) {
  int diff;
  ssize_t len_diff;
  unsigned int len;

  len = a->mv_size;
  len_diff = (ssize_t)a->mv_size - (ssize_t)b->mv_size;
  if (len_diff > 0) {
    len = b->mv_size;
    len_diff = 1;
  }

  diff = memcmp(a->mv_data, b->mv_data, len);
  return diff ? diff : len_diff < 0 ? -1 : len_diff;
}

/** Compare two items in reverse byte order */
static int mdb_cmp_memnr(const MDB_val* a, const MDB_val* b) {
  const unsigned char *p1, *p2, *p1_lim;
  ssize_t len_diff;
  int diff;

  p1_lim = (const unsigned char*)a->mv_data;
  p1 = (const unsigned char*)a->mv_data + a->mv_size;
  p2 = (const unsigned char*)b->mv_data + b->mv_size;

  len_diff = (ssize_t)a->mv_size - (ssize_t)b->mv_size;
  if (len_diff > 0) {
    p1_lim += len_diff;
    len_diff = 1;
  }

  while (p1 > p1_lim) {
    diff = *--p1 - *--p2;
    if (diff)
      return diff;
  }
  return len_diff < 0 ? -1 : len_diff;
}

/** Search for key within a 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).
 * Updates the cursor index with the index of the found entry.
 * If no entry larger or equal to the key is found, returns NULL.
 */
static MDB_node* mdb_node_search(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 %spage %" Yu,
       nkeys,
       IS_LEAF(mp) ? "leaf" : "branch",
       IS_SUBP(mp) ? "sub-" : "",
       mdb_dbg_pgno(mp)));

  low = IS_LEAF(mp) ? 0 : 1;
  high = nkeys - 1;
  cmp = mc->mc_dbx->md_cmp;

  /* Branch pages have no data, so if using integer keys,
   * alignment is guaranteed. Use faster mdb_cmp_int.
   */
  if (cmp == mdb_cmp_cint && IS_BRANCH(mp)) {
    if (NODEPTR(mp, 1)->mn_ksize == sizeof(mdb_size_t))
      cmp = mdb_cmp_long;
    else
      cmp = mdb_cmp_int;
  }

  if (IS_LEAF2(mp)) {
    nodekey.mv_size = mc->mc_db->md_pad;
    node = NODEPTR(mp, 0); /* fake */
    while (low <= high) {
      i = (low + high) >> 1;
      nodekey.mv_data = LEAF2KEY(mp, i, nodekey.mv_size);
      rc = cmp(key, &nodekey);
      DPRINTF(("found leaf index %u [%s], rc = %i", i, DKEY(&nodekey), rc));
      if (rc == 0)
        break;
      if (rc > 0)
        low = i + 1;
      else
        high = i - 1;
    }
  } else {
    while (low <= high) {
      i = (low + high) >> 1;

      node = NODEPTR(mp, i);
      nodekey.mv_size = NODEKSZ(node);
      nodekey.mv_data = NODEKEY(node);

      rc = cmp(key, &nodekey);
#if MDB_DEBUG
      if (IS_LEAF(mp))
        DPRINTF(("found leaf index %u [%s], rc = %i", i, DKEY(&nodekey), rc));
      else
        DPRINTF(
            ("found branch index %u [%s -> %" Yu "], 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 && nkeys > 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;
}

#if 0
static void
mdb_cursor_adjust(MDB_cursor *mc, func)
{
	MDB_cursor *m2;

	for (m2 = mc->mc_txn->mt_cursors[mc->mc_dbi]; m2; m2=m2->mc_next) {
		if (m2->mc_pg[m2->mc_top] == mc->mc_pg[mc->mc_top]) {
			func(mc, m2);
		}
	}
}
#endif

/** Pop a page off the top of the cursor's stack. */
static void mdb_cursor_pop(MDB_cursor* mc) {
  if (mc->mc_snum) {
    DPRINTF(
        ("popping page %" Yu " off db %d cursor %p",
         mc->mc_pg[mc->mc_top]->mp_pgno,
         DDBI(mc),
         (void*)mc));

    mc->mc_snum--;
    if (mc->mc_snum) {
      mc->mc_top--;
    } else {
      mc->mc_flags &= ~C_INITIALIZED;
    }
  }
}

/** Push a page onto the top of the cursor's stack.
 * Set #MDB_TXN_ERROR on failure.
 */
static int mdb_cursor_push(MDB_cursor* mc, MDB_page* mp) {
  DPRINTF(
      ("pushing page %" Yu " on db %d cursor %p",
       mp->mp_pgno,
       DDBI(mc),
       (void*)mc));

  if (mc->mc_snum >= CURSOR_STACK) {
    mc->mc_txn->mt_flags |= MDB_TXN_ERROR;
    return MDB_CURSOR_FULL;
  }

  mc->mc_top = mc->mc_snum++;
  mc->mc_pg[mc->mc_top] = mp;
  mc->mc_ki[mc->mc_top] = 0;

  return MDB_SUCCESS;
}

#ifdef MDB_VL32
/** Map a read-only page.
 * There are two levels of tracking in use, a per-txn list and a per-env list.
 * ref'ing and unref'ing the per-txn list is faster since it requires no
 * locking. Pages are cached in the per-env list for global reuse, and a lock
 * is required. Pages are not immediately unmapped when their refcnt goes to
 * zero; they hang around in case they will be reused again soon.
 *
 * When the per-txn list gets full, all pages with refcnt=0 are purged from the
 * list and their refcnts in the per-env list are decremented.
 *
 * When the per-env list gets full, all pages with refcnt=0 are purged from the
 * list and their pages are unmapped.
 *
 * @note "full" means the list has reached its respective rpcheck threshold.
 * This threshold slowly raises if no pages could be purged on a given check,
 * and returns to its original value when enough pages were purged.
 *
 * If purging doesn't free any slots, filling the per-txn list will return
 * MDB_TXN_FULL, and filling the per-env list returns MDB_MAP_FULL.
 *
 * Reference tracking in a txn is imperfect, pages can linger with non-zero
 * refcnt even without active references. It was deemed to be too invasive
 * to add unrefs in every required location. However, all pages are unref'd
 * at the end of the transaction. This guarantees that no stale references
 * linger in the per-env list.
 *
 * Usually we map chunks of 16 pages at a time, but if an overflow page begins
 * at the tail of the chunk we extend the chunk to include the entire overflow
 * page. Unfortunately, pages can be turned into overflow pages after their
 * chunk was already mapped. In that case we must remap the chunk if the
 * overflow page is referenced. If the chunk's refcnt is 0 we can just remap
 * it, otherwise we temporarily map a new chunk just for the overflow page.
 *
 * @note this chunk handling means we cannot guarantee that a data item
 * returned from the DB will stay alive for the duration of the transaction:
 *   We unref pages as soon as a cursor moves away from the page
 *   A subsequent op may cause a purge, which may unmap any unref'd chunks
 * The caller must copy the data if it must be used later in the same txn.
 *
 * Also - our reference counting revolves around cursors, but overflow pages
 * aren't pointed to by a cursor's page stack. We have to remember them
 * explicitly, in the added mc_ovpg field. A single cursor can only hold a
 * reference to one overflow page at a time.
 *
 * @param[in] txn the transaction for this access.
 * @param[in] pgno the page number for the page to retrieve.
 * @param[out] ret address of a pointer where the page's address will be stored.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_rpage_get(MDB_txn* txn, pgno_t pg0, MDB_page** ret) {
  MDB_env* env = txn->mt_env;
  MDB_page* p;
  MDB_ID3L tl = txn->mt_rpages;
  MDB_ID3L el = env->me_rpages;
  MDB_ID3 id3;
  unsigned x, rem;
  pgno_t pgno;
  int rc, retries = 1;
#ifdef _WIN32
  LARGE_INTEGER off;
  SIZE_T len;
#define SET_OFF(off, val) off.QuadPart = val
#define MAP(rc, env, addr, len, off)                  \
  addr = NULL;                                        \
  rc = NtMapViewOfSection(                            \
      env->me_fmh,                                    \
      GetCurrentProcess(),                            \
      &addr,                                          \
      0,                                              \
      len,                                            \
      &off,                                           \
      &len,                                           \
      ViewUnmap,                                      \
      (env->me_flags & MDB_RDONLY) ? 0 : MEM_RESERVE, \
      PAGE_READONLY);                                 \
  if (rc)                                             \
  rc = mdb_nt2win32(rc)
#else
  off_t off;
  size_t len;
#define SET_OFF(off, val) off = val
#define MAP(rc, env, addr, len, off)                              \
  addr = mmap(NULL, len, PROT_READ, MAP_SHARED, env->me_fd, off); \
  rc = (addr == MAP_FAILED) ? errno : 0
#endif

  /* remember the offset of the actual page number, so we can
   * return the correct pointer at the end.
   */
  rem = pg0 & (MDB_RPAGE_CHUNK - 1);
  pgno = pg0 ^ rem;

  id3.mid = 0;
  x = mdb_mid3l_search(tl, pgno);
  if (x <= tl[0].mid && tl[x].mid == pgno) {
    if (x != tl[0].mid && tl[x + 1].mid == pg0)
      x++;
    /* check for overflow size */
    p = (MDB_page*)((char*)tl[x].mptr + rem * env->me_psize);
    if (IS_OVERFLOW(p) && p->mp_pages + rem > tl[x].mcnt) {
      id3.mcnt = p->mp_pages + rem;
      len = id3.mcnt * env->me_psize;
      SET_OFF(off, pgno * env->me_psize);
      MAP(rc, env, id3.mptr, len, off);
      if (rc)
        return rc;
      /* check for local-only page */
      if (rem) {
        mdb_tassert(txn, tl[x].mid != pg0);
        /* hope there's room to insert this locally.
         * setting mid here tells later code to just insert
         * this id3 instead of searching for a match.
         */
        id3.mid = pg0;
        goto notlocal;
      } else {
        /* ignore the mapping we got from env, use new one */
        tl[x].mptr = id3.mptr;
        tl[x].mcnt = id3.mcnt;
        /* if no active ref, see if we can replace in env */
        if (!tl[x].mref) {
          unsigned i;
          pthread_mutex_lock(&env->me_rpmutex);
          i = mdb_mid3l_search(el, tl[x].mid);
          if (el[i].mref == 1) {
            /* just us, replace it */
            munmap(el[i].mptr, el[i].mcnt * env->me_psize);
            el[i].mptr = tl[x].mptr;
            el[i].mcnt = tl[x].mcnt;
          } else {
            /* there are others, remove ourself */
            el[i].mref--;
          }
          pthread_mutex_unlock(&env->me_rpmutex);
        }
      }
    }
    id3.mptr = tl[x].mptr;
    id3.mcnt = tl[x].mcnt;
    tl[x].mref++;
    goto ok;
  }

notlocal:
  if (tl[0].mid >= MDB_TRPAGE_MAX - txn->mt_rpcheck) {
    unsigned i, y;
    /* purge unref'd pages from our list and unref in env */
    pthread_mutex_lock(&env->me_rpmutex);
  retry:
    y = 0;
    for (i = 1; i <= tl[0].mid; i++) {
      if (!tl[i].mref) {
        if (!y)
          y = i;
        /* tmp overflow pages don't go to env */
        if (tl[i].mid & (MDB_RPAGE_CHUNK - 1)) {
          munmap(tl[i].mptr, tl[i].mcnt * env->me_psize);
          continue;
        }
        x = mdb_mid3l_search(el, tl[i].mid);
        el[x].mref--;
      }
    }
    pthread_mutex_unlock(&env->me_rpmutex);
    if (!y) {
      /* we didn't find any unref'd chunks.
       * if we're out of room, fail.
       */
      if (tl[0].mid >= MDB_TRPAGE_MAX)
        return MDB_TXN_FULL;
      /* otherwise, raise threshold for next time around
       * and let this go.
       */
      txn->mt_rpcheck /= 2;
    } else {
      /* we found some unused; consolidate the list */
      for (i = y + 1; i <= tl[0].mid; i++)
        if (tl[i].mref)
          tl[y++] = tl[i];
      tl[0].mid = y - 1;
      /* decrease the check threshold toward its original value */
      if (!txn->mt_rpcheck)
        txn->mt_rpcheck = 1;
      while (txn->mt_rpcheck < tl[0].mid &&
             txn->mt_rpcheck < MDB_TRPAGE_SIZE / 2)
        txn->mt_rpcheck *= 2;
    }
  }
  if (tl[0].mid < MDB_TRPAGE_SIZE) {
    id3.mref = 1;
    if (id3.mid)
      goto found;
    /* don't map past last written page in read-only envs */
    if ((env->me_flags & MDB_RDONLY) &&
        pgno + MDB_RPAGE_CHUNK - 1 > txn->mt_last_pgno)
      id3.mcnt = txn->mt_last_pgno + 1 - pgno;
    else
      id3.mcnt = MDB_RPAGE_CHUNK;
    len = id3.mcnt * env->me_psize;
    id3.mid = pgno;

    /* search for page in env */
    pthread_mutex_lock(&env->me_rpmutex);
    x = mdb_mid3l_search(el, pgno);
    if (x <= el[0].mid && el[x].mid == pgno) {
      id3.mptr = el[x].mptr;
      id3.mcnt = el[x].mcnt;
      /* check for overflow size */
      p = (MDB_page*)((char*)id3.mptr + rem * env->me_psize);
      if (IS_OVERFLOW(p) && p->mp_pages + rem > id3.mcnt) {
        id3.mcnt = p->mp_pages + rem;
        len = id3.mcnt * env->me_psize;
        SET_OFF(off, pgno * env->me_psize);
        MAP(rc, env, id3.mptr, len, off);
        if (rc)
          goto fail;
        if (!el[x].mref) {
          munmap(el[x].mptr, env->me_psize * el[x].mcnt);
          el[x].mptr = id3.mptr;
          el[x].mcnt = id3.mcnt;
        } else {
          id3.mid = pg0;
          pthread_mutex_unlock(&env->me_rpmutex);
          goto found;
        }
      }
      el[x].mref++;
      pthread_mutex_unlock(&env->me_rpmutex);
      goto found;
    }
    if (el[0].mid >= MDB_ERPAGE_MAX - env->me_rpcheck) {
      /* purge unref'd pages */
      unsigned i, y = 0;
      for (i = 1; i <= el[0].mid; i++) {
        if (!el[i].mref) {
          if (!y)
            y = i;
          munmap(el[i].mptr, env->me_psize * el[i].mcnt);
        }
      }
      if (!y) {
        if (retries) {
          /* see if we can unref some local pages */
          retries--;
          id3.mid = 0;
          goto retry;
        }
        if (el[0].mid >= MDB_ERPAGE_MAX) {
          pthread_mutex_unlock(&env->me_rpmutex);
          return MDB_MAP_FULL;
        }
        env->me_rpcheck /= 2;
      } else {
        for (i = y + 1; i <= el[0].mid; i++)
          if (el[i].mref)
            el[y++] = el[i];
        el[0].mid = y - 1;
        if (!env->me_rpcheck)
          env->me_rpcheck = 1;
        while (env->me_rpcheck < el[0].mid &&
               env->me_rpcheck < MDB_ERPAGE_SIZE / 2)
          env->me_rpcheck *= 2;
      }
    }
    SET_OFF(off, pgno * env->me_psize);
    MAP(rc, env, id3.mptr, len, off);
    if (rc) {
    fail:
      pthread_mutex_unlock(&env->me_rpmutex);
      return rc;
    }
    /* check for overflow size */
    p = (MDB_page*)((char*)id3.mptr + rem * env->me_psize);
    if (IS_OVERFLOW(p) && p->mp_pages + rem > id3.mcnt) {
      id3.mcnt = p->mp_pages + rem;
      munmap(id3.mptr, len);
      len = id3.mcnt * env->me_psize;
      MAP(rc, env, id3.mptr, len, off);
      if (rc)
        goto fail;
    }
    mdb_mid3l_insert(el, &id3);
    pthread_mutex_unlock(&env->me_rpmutex);
  found:
    mdb_mid3l_insert(tl, &id3);
  } else {
    return MDB_TXN_FULL;
  }
ok:
  p = (MDB_page*)((char*)id3.mptr + rem * env->me_psize);
#if MDB_DEBUG /* we don't need this check any more */
  if (IS_OVERFLOW(p)) {
    mdb_tassert(txn, p->mp_pages + rem <= id3.mcnt);
  }
#endif
  *ret = p;
  return MDB_SUCCESS;
}
#endif

/** Find the address of the page corresponding to a given page number.
 * Set #MDB_TXN_ERROR on failure.
 * @param[in] mc the cursor accessing the page.
 * @param[in] pgno the page number for the page to retrieve.
 * @param[out] ret address of a pointer where the page's address will be stored.
 * @param[out] lvl dirty_list inheritance level of found page. 1=current txn,
 * 0=mapped page.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_get(MDB_cursor* mc, pgno_t pgno, MDB_page** ret, int* lvl) {
  MDB_txn* txn = mc->mc_txn;
  MDB_page* p = NULL;
  int level;

  if (!(mc->mc_flags & (C_ORIG_RDONLY | C_WRITEMAP))) {
    MDB_txn* tx2 = txn;
    level = 1;
    do {
      MDB_ID2L dl = tx2->mt_u.dirty_list;
      unsigned x;
      /* Spilled pages were dirtied in this txn and flushed
       * because the dirty list got full. Bring this page
       * back in from the map (but don't unspill it here,
       * leave that unless page_touch happens again).
       */
      if (tx2->mt_spill_pgs) {
        MDB_ID pn = pgno << 1;
        x = mdb_midl_search(tx2->mt_spill_pgs, pn);
        if (x <= tx2->mt_spill_pgs[0] && tx2->mt_spill_pgs[x] == pn) {
          goto mapped;
        }
      }
      if (dl[0].mid) {
        unsigned x = mdb_mid2l_search(dl, pgno);
        if (x <= dl[0].mid && dl[x].mid == pgno) {
          p = dl[x].mptr;
          goto done;
        }
      }
      level++;
    } while ((tx2 = tx2->mt_parent) != NULL);
  }

  if (pgno >= txn->mt_next_pgno) {
    DPRINTF(("page %" Yu " not found", pgno));
    txn->mt_flags |= MDB_TXN_ERROR;
    return MDB_PAGE_NOTFOUND;
  }

  level = 0;

mapped: {
#ifdef MDB_VL32
  int rc = mdb_rpage_get(txn, pgno, &p);
  if (rc) {
    txn->mt_flags |= MDB_TXN_ERROR;
    return rc;
  }
#else
  MDB_env* env = txn->mt_env;
  p = (MDB_page*)(env->me_map + env->me_psize * pgno);
#endif
}

done:
  *ret = p;
  if (lvl)
    *lvl = level;
  return MDB_SUCCESS;
}

/** Finish #mdb_page_search() / #mdb_page_search_lowest().
 *	The cursor is at the root page, set up the rest of it.
 */
static int mdb_page_search_root(MDB_cursor* mc, MDB_val* key, int flags) {
  MDB_page* mp = mc->mc_pg[mc->mc_top];
  int rc;
  DKBUF;

  while (IS_BRANCH(mp)) {
    MDB_node* node;
    indx_t i;

    DPRINTF(("branch page %" Yu " has %u keys", mp->mp_pgno, NUMKEYS(mp)));
    /* Don't assert on branch pages in the FreeDB. We can get here
     * while in the process of rebalancing a FreeDB branch page; we must
     * let that proceed. ITS#8336
     */
    mdb_cassert(mc, !mc->mc_dbi || NUMKEYS(mp) > 1);
    DPRINTF(("found index 0 to page %" Yu, NODEPGNO(NODEPTR(mp, 0))));

    if (flags & (MDB_PS_FIRST | MDB_PS_LAST)) {
      i = 0;
      if (flags & MDB_PS_LAST) {
        i = NUMKEYS(mp) - 1;
        /* if already init'd, see if we're already in right place */
        if (mc->mc_flags & C_INITIALIZED) {
          if (mc->mc_ki[mc->mc_top] == i) {
            mc->mc_top = mc->mc_snum++;
            mp = mc->mc_pg[mc->mc_top];
            goto ready;
          }
        }
      }
    } else {
      int exact;
      node = mdb_node_search(mc, key, &exact);
      if (node == NULL)
        i = NUMKEYS(mp) - 1;
      else {
        i = mc->mc_ki[mc->mc_top];
        if (!exact) {
          mdb_cassert(mc, i > 0);
          i--;
        }
      }
      DPRINTF(("following index %u for key [%s]", i, DKEY(key)));
    }

    mdb_cassert(mc, i < NUMKEYS(mp));
    node = NODEPTR(mp, i);

    if ((rc = mdb_page_get(mc, NODEPGNO(node), &mp, NULL)) != 0)
      return rc;

    mc->mc_ki[mc->mc_top] = i;
    if ((rc = mdb_cursor_push(mc, mp)))
      return rc;

  ready:
    if (flags & MDB_PS_MODIFY) {
      if ((rc = mdb_page_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));
    mc->mc_txn->mt_flags |= MDB_TXN_ERROR;
    return MDB_CORRUPTED;
  }

  DPRINTF(
      ("found leaf page %" Yu " for key [%s]",
       mp->mp_pgno,
       key ? DKEY(key) : "null"));
  mc->mc_flags |= C_INITIALIZED;
  mc->mc_flags &= ~C_EOF;

  return MDB_SUCCESS;
}

/** Search for the lowest key under the current branch page.
 * This just bypasses a NUMKEYS check in the current page
 * before calling mdb_page_search_root(), because the callers
 * are all in situations where the current page is known to
 * be underfilled.
 */
static int mdb_page_search_lowest(MDB_cursor* mc) {
  MDB_page* mp = mc->mc_pg[mc->mc_top];
  MDB_node* node = NODEPTR(mp, 0);
  int rc;

  if ((rc = mdb_page_get(mc, NODEPGNO(node), &mp, NULL)) != 0)
    return rc;

  mc->mc_ki[mc->mc_top] = 0;
  if ((rc = mdb_cursor_push(mc, mp)))
    return rc;
  return mdb_page_search_root(mc, NULL, MDB_PS_FIRST);
}

/** Search for the page a given key should be in.
 * Push it and its parent pages on the cursor stack.
 * @param[in,out] mc the cursor for this operation.
 * @param[in] key the key to search for, or NULL for first/last page.
 * @param[in] flags If MDB_PS_MODIFY is set, visited pages in the DB
 *   are touched (updated with new page numbers).
 *   If MDB_PS_FIRST or MDB_PS_LAST is set, find first or last leaf.
 *   This is used by #mdb_cursor_first() and #mdb_cursor_last().
 *   If MDB_PS_ROOTONLY set, just fetch root node, no further lookups.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_search(MDB_cursor* mc, MDB_val* key, int flags) {
  int rc;
  pgno_t root;

  /* Make sure the txn is still viable, then find the root from
   * the txn's db table and set it as the root of the cursor's stack.
   */
  if (mc->mc_txn->mt_flags & MDB_TXN_BLOCKED) {
    DPUTS("transaction may not be used now");
    return MDB_BAD_TXN;
  } else {
    /* Make sure we're using an up-to-date root */
    if (*mc->mc_dbflag & DB_STALE) {
      MDB_cursor mc2;
      if (TXN_DBI_CHANGED(mc->mc_txn, mc->mc_dbi))
        return MDB_BAD_DBI;
      mdb_cursor_init(&mc2, mc->mc_txn, MAIN_DBI, NULL);
      rc = mdb_page_search(&mc2, &mc->mc_dbx->md_name, 0);
      if (rc)
        return rc;
      {
        MDB_val data;
        int exact = 0;
        uint16_t flags;
        MDB_node* leaf = mdb_node_search(&mc2, &mc->mc_dbx->md_name, &exact);
        if (!exact)
          return MDB_BAD_DBI;
        if ((leaf->mn_flags & (F_DUPDATA | F_SUBDATA)) != F_SUBDATA)
          return MDB_INCOMPATIBLE; /* not a named DB */
        rc = mdb_node_read(&mc2, leaf, &data);
        if (rc)
          return rc;
        memcpy(
            &flags,
            ((char*)data.mv_data + offsetof(MDB_db, md_flags)),
            sizeof(uint16_t));
        /* The txn may not know this DBI, or another process may
         * have dropped and recreated the DB with other flags.
         */
        if ((mc->mc_db->md_flags & PERSISTENT_FLAGS) != flags)
          return MDB_INCOMPATIBLE;
        memcpy(mc->mc_db, data.mv_data, sizeof(MDB_db));
      }
      *mc->mc_dbflag &= ~DB_STALE;
    }
    root = mc->mc_db->md_root;

    if (root == P_INVALID) { /* Tree is empty. */
      DPUTS("tree is empty");
      return MDB_NOTFOUND;
    }
  }

  mdb_cassert(mc, root > 1);
  if (!mc->mc_pg[0] || mc->mc_pg[0]->mp_pgno != root) {
#ifdef MDB_VL32
    if (mc->mc_pg[0])
      MDB_PAGE_UNREF(mc->mc_txn, mc->mc_pg[0]);
#endif
    if ((rc = mdb_page_get(mc, root, &mc->mc_pg[0], NULL)) != 0)
      return rc;
  }

#ifdef MDB_VL32
  {
    int i;
    for (i = 1; i < mc->mc_snum; i++)
      MDB_PAGE_UNREF(mc->mc_txn, mc->mc_pg[i]);
  }
#endif
  mc->mc_snum = 1;
  mc->mc_top = 0;

  DPRINTF(
      ("db %d root page %" Yu " has flags 0x%X",
       DDBI(mc),
       root,
       mc->mc_pg[0]->mp_flags));

  if (flags & MDB_PS_MODIFY) {
    if ((rc = mdb_page_touch(mc)))
      return rc;
  }

  if (flags & MDB_PS_ROOTONLY)
    return MDB_SUCCESS;

  return mdb_page_search_root(mc, key, flags);
}

static int mdb_ovpage_free(MDB_cursor* mc, MDB_page* mp) {
  MDB_txn* txn = mc->mc_txn;
  pgno_t pg = mp->mp_pgno;
  unsigned x = 0, ovpages = mp->mp_pages;
  MDB_env* env = txn->mt_env;
  MDB_IDL sl = txn->mt_spill_pgs;
  MDB_ID pn = pg << 1;
  int rc;

  DPRINTF(("free ov page %" Yu " (%d)", pg, ovpages));
  /* If the page is dirty or on the spill list we just acquired it,
   * so we should give it back to our current free list, if any.
   * Otherwise put it onto the list of pages we freed in this txn.
   *
   * Won't create me_pghead: me_pglast must be inited along with it.
   * Unsupported in nested txns: They would need to hide the page
   * range in ancestor txns' dirty and spilled lists.
   */
  if (env->me_pghead && !txn->mt_parent &&
      ((mp->mp_flags & P_DIRTY) ||
       (sl && (x = mdb_midl_search(sl, pn)) <= sl[0] && sl[x] == pn))) {
    unsigned i, j;
    pgno_t* mop;
    MDB_ID2 *dl, ix, iy;
    rc = mdb_midl_need(&env->me_pghead, ovpages);
    if (rc)
      return rc;
    if (!(mp->mp_flags & P_DIRTY)) {
      /* This page is no longer spilled */
      if (x == sl[0])
        sl[0]--;
      else
        sl[x] |= 1;
      goto release;
    }
    /* Remove from dirty list */
    dl = txn->mt_u.dirty_list;
    x = dl[0].mid--;
    for (ix = dl[x]; ix.mptr != mp; ix = iy) {
      if (x > 1) {
        x--;
        iy = dl[x];
        dl[x] = ix;
      } else {
        mdb_cassert(mc, x > 1);
        j = ++(dl[0].mid);
        dl[j] = ix; /* Unsorted. OK when MDB_TXN_ERROR. */
        txn->mt_flags |= MDB_TXN_ERROR;
        return MDB_PROBLEM;
      }
    }
    txn->mt_dirty_room++;
    if (!(env->me_flags & MDB_WRITEMAP))
      mdb_dpage_free(env, mp);
  release:
    /* Insert in me_pghead */
    mop = env->me_pghead;
    j = mop[0] + ovpages;
    for (i = mop[0]; i && mop[i] < pg; i--)
      mop[j--] = mop[i];
    while (j > i)
      mop[j--] = pg++;
    mop[0] += ovpages;
  } else {
    rc = mdb_midl_append_range(&txn->mt_free_pgs, pg, ovpages);
    if (rc)
      return rc;
  }
#ifdef MDB_VL32
  if (mc->mc_ovpg == mp)
    mc->mc_ovpg = NULL;
#endif
  mc->mc_db->md_overflow_pages -= ovpages;
  return 0;
}

/** Return the data associated with a given node.
 * @param[in] mc The cursor for this operation.
 * @param[in] leaf The node being read.
 * @param[out] data Updated to point to the node's data.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_node_read(MDB_cursor* mc, MDB_node* leaf, MDB_val* data) {
  MDB_page* omp; /* overflow page */
  pgno_t pgno;
  int rc;

  if (MC_OVPG(mc)) {
    MDB_PAGE_UNREF(mc->mc_txn, MC_OVPG(mc));
    MC_SET_OVPG(mc, NULL);
  }
  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_page_get(mc, pgno, &omp, NULL)) != 0) {
    DPRINTF(("read overflow page %" Yu " failed", pgno));
    return rc;
  }
  data->mv_data = METADATA(omp);
  MC_SET_OVPG(mc, 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, rc;
  DKBUF;

  DPRINTF(("===> get db %u key [%s]", dbi, DKEY(key)));

  if (!key || !data || !TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;

  if (txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  mdb_cursor_init(&mc, txn, dbi, &mx);
  rc = mdb_cursor_set(&mc, key, data, MDB_SET, &exact);
  /* unref all the pages when MDB_VL32 - caller must copy the data
   * before doing anything else
   */
  MDB_CURSOR_UNREF(&mc, 1);
  return rc;
}

/** Find a sibling for a page.
 * Replaces the page at the top of the cursor's stack with the
 * specified sibling, if one exists.
 * @param[in] mc The cursor for this operation.
 * @param[in] move_right Non-zero if the right sibling is requested,
 * otherwise the left sibling.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_cursor_sibling(MDB_cursor* mc, int move_right) {
  int rc;
  MDB_node* indx;
  MDB_page* mp;
#ifdef MDB_VL32
  MDB_page* op;
#endif

  if (mc->mc_snum < 2) {
    return MDB_NOTFOUND; /* root has no siblings */
  }

#ifdef MDB_VL32
  op = mc->mc_pg[mc->mc_top];
#endif
  mdb_cursor_pop(mc);
  DPRINTF(
      ("parent page is page %" Yu ", index %u",
       mc->mc_pg[mc->mc_top]->mp_pgno,
       mc->mc_ki[mc->mc_top]));

  if (move_right
          ? (mc->mc_ki[mc->mc_top] + 1u >= NUMKEYS(mc->mc_pg[mc->mc_top]))
          : (mc->mc_ki[mc->mc_top] == 0)) {
    DPRINTF(
        ("no more keys left, moving to %s sibling",
         move_right ? "right" : "left"));
    if ((rc = mdb_cursor_sibling(mc, move_right)) != MDB_SUCCESS) {
      /* undo cursor_pop before returning */
      mc->mc_top++;
      mc->mc_snum++;
      return rc;
    }
  } else {
    if (move_right)
      mc->mc_ki[mc->mc_top]++;
    else
      mc->mc_ki[mc->mc_top]--;
    DPRINTF(
        ("just moving to %s index key %u",
         move_right ? "right" : "left",
         mc->mc_ki[mc->mc_top]));
  }
  mdb_cassert(mc, IS_BRANCH(mc->mc_pg[mc->mc_top]));

  MDB_PAGE_UNREF(mc->mc_txn, op);

  indx = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);
  if ((rc = mdb_page_get(mc, NODEPGNO(indx), &mp, NULL)) != 0) {
    /* mc will be inconsistent if caller does mc_snum++ as above */
    mc->mc_flags &= ~(C_INITIALIZED | C_EOF);
    return rc;
  }

  mdb_cursor_push(mc, mp);
  if (!move_right)
    mc->mc_ki[mc->mc_top] = NUMKEYS(mp) - 1;

  return MDB_SUCCESS;
}

/** Move the cursor to the next data item. */
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_DEL && op == MDB_NEXT_DUP))
    return MDB_NOTFOUND;

  if (!(mc->mc_flags & C_INITIALIZED))
    return mdb_cursor_first(mc, key, data);

  mp = mc->mc_pg[mc->mc_top];

  if (mc->mc_flags & C_EOF) {
    if (mc->mc_ki[mc->mc_top] >= NUMKEYS(mp) - 1)
      return MDB_NOTFOUND;
    mc->mc_flags ^= C_EOF;
  }

  if (mc->mc_db->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_NOTFOUND) {
          if (rc == MDB_SUCCESS)
            MDB_GET_KEY(leaf, key);
          return rc;
        }
      } else {
        MDB_CURSOR_UNREF(&mc->mc_xcursor->mx_cursor, 0);
      }
    } else {
      mc->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
      if (op == MDB_NEXT_DUP)
        return MDB_NOTFOUND;
    }
  }

  DPRINTF(
      ("cursor_next: top page is %" Yu " in cursor %p",
       mdb_dbg_pgno(mp),
       (void*)mc));
  if (mc->mc_flags & C_DEL) {
    mc->mc_flags ^= C_DEL;
    goto skip;
  }

  if (mc->mc_ki[mc->mc_top] + 1u >= NUMKEYS(mp)) {
    DPUTS("=====> move to next sibling page");
    if ((rc = mdb_cursor_sibling(mc, 1)) != MDB_SUCCESS) {
      mc->mc_flags |= C_EOF;
      return rc;
    }
    mp = mc->mc_pg[mc->mc_top];
    DPRINTF(
        ("next page is %" Yu ", key index %u",
         mp->mp_pgno,
         mc->mc_ki[mc->mc_top]));
  } else
    mc->mc_ki[mc->mc_top]++;

skip:
  DPRINTF(
      ("==> cursor points to page %" Yu " with %u keys, key index %u",
       mdb_dbg_pgno(mp),
       NUMKEYS(mp),
       mc->mc_ki[mc->mc_top]));

  if (IS_LEAF2(mp)) {
    key->mv_size = mc->mc_db->md_pad;
    key->mv_data = LEAF2KEY(mp, mc->mc_ki[mc->mc_top], key->mv_size);
    return MDB_SUCCESS;
  }

  mdb_cassert(mc, 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);
    rc = mdb_cursor_first(&mc->mc_xcursor->mx_cursor, data, NULL);
    if (rc != MDB_SUCCESS)
      return rc;
  } else if (data) {
    if ((rc = mdb_node_read(mc, leaf, data)) != MDB_SUCCESS)
      return rc;
  }

  MDB_GET_KEY(leaf, key);
  return MDB_SUCCESS;
}

/** Move the cursor to the previous data item. */
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;

  if (!(mc->mc_flags & C_INITIALIZED)) {
    rc = mdb_cursor_last(mc, key, data);
    if (rc)
      return rc;
    mc->mc_ki[mc->mc_top]++;
  }

  mp = mc->mc_pg[mc->mc_top];

  if ((mc->mc_db->md_flags & MDB_DUPSORT) &&
      mc->mc_ki[mc->mc_top] < NUMKEYS(mp)) {
    leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]);
    if (F_ISSET(leaf->mn_flags, F_DUPDATA)) {
      if (op == MDB_PREV || op == MDB_PREV_DUP) {
        rc = mdb_cursor_prev(&mc->mc_xcursor->mx_cursor, data, NULL, MDB_PREV);
        if (op != MDB_PREV || rc != MDB_NOTFOUND) {
          if (rc == MDB_SUCCESS) {
            MDB_GET_KEY(leaf, key);
            mc->mc_flags &= ~C_EOF;
          }
          return rc;
        }
      } else {
        MDB_CURSOR_UNREF(&mc->mc_xcursor->mx_cursor, 0);
      }
    } else {
      mc->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
      if (op == MDB_PREV_DUP)
        return MDB_NOTFOUND;
    }
  }

  DPRINTF(
      ("cursor_prev: top page is %" Yu " in cursor %p",
       mdb_dbg_pgno(mp),
       (void*)mc));

  mc->mc_flags &= ~(C_EOF | C_DEL);

  if (mc->mc_ki[mc->mc_top] == 0) {
    DPUTS("=====> move to prev sibling page");
    if ((rc = mdb_cursor_sibling(mc, 0)) != MDB_SUCCESS) {
      return rc;
    }
    mp = mc->mc_pg[mc->mc_top];
    mc->mc_ki[mc->mc_top] = NUMKEYS(mp) - 1;
    DPRINTF(
        ("prev page is %" Yu ", key index %u",
         mp->mp_pgno,
         mc->mc_ki[mc->mc_top]));
  } else
    mc->mc_ki[mc->mc_top]--;

  DPRINTF(
      ("==> cursor points to page %" Yu " with %u keys, key index %u",
       mdb_dbg_pgno(mp),
       NUMKEYS(mp),
       mc->mc_ki[mc->mc_top]));

  if (!IS_LEAF(mp))
    return MDB_CORRUPTED;

  if (IS_LEAF2(mp)) {
    key->mv_size = mc->mc_db->md_pad;
    key->mv_data = LEAF2KEY(mp, mc->mc_ki[mc->mc_top], key->mv_size);
    return MDB_SUCCESS;
  }

  leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]);

  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 != MDB_SUCCESS)
      return rc;
  } else if (data) {
    if ((rc = mdb_node_read(mc, leaf, data)) != MDB_SUCCESS)
      return rc;
  }

  MDB_GET_KEY(leaf, key);
  return MDB_SUCCESS;
}

/** Set the cursor on a specific data item. */
static int mdb_cursor_set(
    MDB_cursor* mc,
    MDB_val* key,
    MDB_val* data,
    MDB_cursor_op op,
    int* exactp) {
  int rc;
  MDB_page* mp;
  MDB_node* leaf = NULL;
  DKBUF;

  if (key->mv_size == 0)
    return MDB_BAD_VALSIZE;

  if (mc->mc_xcursor) {
    MDB_CURSOR_UNREF(&mc->mc_xcursor->mx_cursor, 0);
    mc->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
  }

  /* See if we're already on the right page */
  if (mc->mc_flags & C_INITIALIZED) {
    MDB_val nodekey;

    mp = mc->mc_pg[mc->mc_top];
    if (!NUMKEYS(mp)) {
      mc->mc_ki[mc->mc_top] = 0;
      return MDB_NOTFOUND;
    }
    if (MP_FLAGS(mp) & P_LEAF2) {
      nodekey.mv_size = mc->mc_db->md_pad;
      nodekey.mv_data = LEAF2KEY(mp, 0, nodekey.mv_size);
    } else {
      leaf = NODEPTR(mp, 0);
      MDB_GET_KEY2(leaf, nodekey);
    }
    rc = mc->mc_dbx->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;
      if (exactp)
        *exactp = 1;
      goto set1;
    }
    if (rc > 0) {
      unsigned int i;
      unsigned int nkeys = NUMKEYS(mp);
      if (nkeys > 1) {
        if (MP_FLAGS(mp) & P_LEAF2) {
          nodekey.mv_data = LEAF2KEY(mp, nkeys - 1, nodekey.mv_size);
        } else {
          leaf = NODEPTR(mp, nkeys - 1);
          MDB_GET_KEY2(leaf, nodekey);
        }
        rc = mc->mc_dbx->md_cmp(key, &nodekey);
        if (rc == 0) {
          /* last node was the one we wanted */
          mc->mc_ki[mc->mc_top] = nkeys - 1;
          if (exactp)
            *exactp = 1;
          goto set1;
        }
        if (rc < 0) {
          if (mc->mc_ki[mc->mc_top] < NUMKEYS(mp)) {
            /* This is definitely the right page, skip search_page */
            if (MP_FLAGS(mp) & P_LEAF2) {
              nodekey.mv_data =
                  LEAF2KEY(mp, mc->mc_ki[mc->mc_top], nodekey.mv_size);
            } else {
              leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]);
              MDB_GET_KEY2(leaf, nodekey);
            }
            rc = mc->mc_dbx->md_cmp(key, &nodekey);
            if (rc == 0) {
              /* current node was the one we wanted */
              if (exactp)
                *exactp = 1;
              goto set1;
            }
          }
          rc = 0;
          mc->mc_flags &= ~C_EOF;
          goto set2;
        }
      }
      /* If any parents have right-sibs, search.
       * Otherwise, there's nothing further.
       */
      for (i = 0; i < mc->mc_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] = nkeys;
        return MDB_NOTFOUND;
      }
    }
    if (!mc->mc_top) {
      /* There are no other pages */
      mc->mc_ki[mc->mc_top] = 0;
      if (op == MDB_SET_RANGE && !exactp) {
        rc = 0;
        goto set1;
      } else
        return MDB_NOTFOUND;
    }
  } else {
    mc->mc_pg[0] = 0;
  }

  rc = mdb_page_search(mc, key, 0);
  if (rc != MDB_SUCCESS)
    return rc;

  mp = mc->mc_pg[mc->mc_top];
  mdb_cassert(mc, IS_LEAF(mp));

set2:
  leaf = mdb_node_search(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_cursor_sibling(mc, 1)) != MDB_SUCCESS) {
      mc->mc_flags |= C_EOF;
      return rc; /* no entries matched */
    }
    mp = mc->mc_pg[mc->mc_top];
    mdb_cassert(mc, IS_LEAF(mp));
    leaf = NODEPTR(mp, 0);
  }

set1:
  mc->mc_flags |= C_INITIALIZED;
  mc->mc_flags &= ~C_EOF;

  if (IS_LEAF2(mp)) {
    if (op == MDB_SET_RANGE || op == MDB_SET_KEY) {
      key->mv_size = mc->mc_db->md_pad;
      key->mv_data = LEAF2KEY(mp, 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 (op == MDB_SET || op == MDB_SET_KEY || 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 (data) {
    if (op == MDB_GET_BOTH || op == MDB_GET_BOTH_RANGE) {
      MDB_val olddata;
      MDB_cmp_func* dcmp;
      if ((rc = mdb_node_read(mc, leaf, &olddata)) != MDB_SUCCESS)
        return rc;
      dcmp = mc->mc_dbx->md_dcmp;
      if (NEED_CMP_CLONG(dcmp, olddata.mv_size))
        dcmp = mdb_cmp_clong;
      rc = dcmp(data, &olddata);
      if (rc) {
        if (op == MDB_GET_BOTH || rc > 0)
          return MDB_NOTFOUND;
        rc = 0;
      }
      *data = olddata;

    } else {
      if (mc->mc_xcursor)
        mc->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
      if ((rc = mdb_node_read(mc, leaf, data)) != MDB_SUCCESS)
        return rc;
    }
  }

  /* The key already matches in all other cases */
  if (op == MDB_SET_RANGE || op == MDB_SET_KEY)
    MDB_GET_KEY(leaf, key);
  DPRINTF(("==> cursor placed on key [%s]", DKEY(key)));

  return rc;
}

/** Move the cursor to the first item in the database. */
static int mdb_cursor_first(MDB_cursor* mc, MDB_val* key, MDB_val* data) {
  int rc;
  MDB_node* leaf;

  if (mc->mc_xcursor) {
    MDB_CURSOR_UNREF(&mc->mc_xcursor->mx_cursor, 0);
    mc->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
  }

  if (!(mc->mc_flags & C_INITIALIZED) || mc->mc_top) {
    rc = mdb_page_search(mc, NULL, MDB_PS_FIRST);
    if (rc != MDB_SUCCESS)
      return rc;
  }
  mdb_cassert(mc, 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;

  mc->mc_ki[mc->mc_top] = 0;

  if (IS_LEAF2(mc->mc_pg[mc->mc_top])) {
    if (key) {
      key->mv_size = mc->mc_db->md_pad;
      key->mv_data = LEAF2KEY(mc->mc_pg[mc->mc_top], 0, key->mv_size);
    }
    return MDB_SUCCESS;
  }

  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 (data) {
    if ((rc = mdb_node_read(mc, leaf, data)) != MDB_SUCCESS)
      return rc;
  }

  MDB_GET_KEY(leaf, key);
  return MDB_SUCCESS;
}

/** Move the cursor to the last item in the database. */
static int mdb_cursor_last(MDB_cursor* mc, MDB_val* key, MDB_val* data) {
  int rc;
  MDB_node* leaf;

  if (mc->mc_xcursor) {
    MDB_CURSOR_UNREF(&mc->mc_xcursor->mx_cursor, 0);
    mc->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
  }

  if (!(mc->mc_flags & C_INITIALIZED) || mc->mc_top) {
    rc = mdb_page_search(mc, NULL, MDB_PS_LAST);
    if (rc != MDB_SUCCESS)
      return rc;
  }
  mdb_cassert(mc, IS_LEAF(mc->mc_pg[mc->mc_top]));

  mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top]) - 1;
  mc->mc_flags |= C_INITIALIZED | C_EOF;
  leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);

  if (IS_LEAF2(mc->mc_pg[mc->mc_top])) {
    if (key) {
      key->mv_size = mc->mc_db->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);
    rc = mdb_cursor_last(&mc->mc_xcursor->mx_cursor, data, NULL);
    if (rc)
      return rc;
  } else if (data) {
    if ((rc = mdb_node_read(mc, leaf, data)) != MDB_SUCCESS)
      return rc;
  }

  MDB_GET_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;
  int (*mfunc)(MDB_cursor* mc, MDB_val* key, MDB_val* data);

  if (mc == NULL)
    return EINVAL;

  if (mc->mc_txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  switch (op) {
    case MDB_GET_CURRENT:
      if (!(mc->mc_flags & C_INITIALIZED)) {
        rc = EINVAL;
      } else {
        MDB_page* mp = mc->mc_pg[mc->mc_top];
        int nkeys = NUMKEYS(mp);
        if (!nkeys || mc->mc_ki[mc->mc_top] >= nkeys) {
          mc->mc_ki[mc->mc_top] = nkeys;
          rc = MDB_NOTFOUND;
          break;
        }
        rc = MDB_SUCCESS;
        if (IS_LEAF2(mp)) {
          key->mv_size = mc->mc_db->md_pad;
          key->mv_data = LEAF2KEY(mp, mc->mc_ki[mc->mc_top], key->mv_size);
        } else {
          MDB_node* leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]);
          MDB_GET_KEY(leaf, key);
          if (data) {
            if (F_ISSET(leaf->mn_flags, F_DUPDATA)) {
              rc = mdb_cursor_get(
                  &mc->mc_xcursor->mx_cursor, data, NULL, MDB_GET_CURRENT);
            } else {
              rc = mdb_node_read(mc, leaf, data);
            }
          }
        }
      }
      break;
    case MDB_GET_BOTH:
    case MDB_GET_BOTH_RANGE:
      if (data == NULL) {
        rc = EINVAL;
        break;
      }
      if (mc->mc_xcursor == NULL) {
        rc = MDB_INCOMPATIBLE;
        break;
      }
      /* FALLTHRU */
    case MDB_SET:
    case MDB_SET_KEY:
    case MDB_SET_RANGE:
      if (key == NULL) {
        rc = EINVAL;
      } else {
        rc = mdb_cursor_set(
            mc, key, data, op, op == MDB_SET_RANGE ? NULL : &exact);
      }
      break;
    case MDB_GET_MULTIPLE:
      if (data == NULL || !(mc->mc_flags & C_INITIALIZED)) {
        rc = EINVAL;
        break;
      }
      if (!(mc->mc_db->md_flags & MDB_DUPFIXED)) {
        rc = MDB_INCOMPATIBLE;
        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) {
        rc = EINVAL;
        break;
      }
      if (!(mc->mc_db->md_flags & MDB_DUPFIXED)) {
        rc = MDB_INCOMPATIBLE;
        break;
      }
      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_db->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_PREV_MULTIPLE:
      if (data == NULL) {
        rc = EINVAL;
        break;
      }
      if (!(mc->mc_db->md_flags & MDB_DUPFIXED)) {
        rc = MDB_INCOMPATIBLE;
        break;
      }
      if (!(mc->mc_flags & C_INITIALIZED))
        rc = mdb_cursor_last(mc, key, data);
      else
        rc = MDB_SUCCESS;
      if (rc == MDB_SUCCESS) {
        MDB_cursor* mx = &mc->mc_xcursor->mx_cursor;
        if (mx->mc_flags & C_INITIALIZED) {
          rc = mdb_cursor_sibling(mx, 0);
          if (rc == MDB_SUCCESS)
            goto fetchm;
        } else {
          rc = MDB_NOTFOUND;
        }
      }
      break;
    case MDB_NEXT:
    case MDB_NEXT_DUP:
    case MDB_NEXT_NODUP:
      rc = mdb_cursor_next(mc, key, data, op);
      break;
    case MDB_PREV:
    case MDB_PREV_DUP:
    case MDB_PREV_NODUP:
      rc = mdb_cursor_prev(mc, key, data, op);
      break;
    case MDB_FIRST:
      rc = mdb_cursor_first(mc, key, data);
      break;
    case MDB_FIRST_DUP:
      mfunc = mdb_cursor_first;
    mmove:
      if (data == NULL || !(mc->mc_flags & C_INITIALIZED)) {
        rc = EINVAL;
        break;
      }
      if (mc->mc_xcursor == NULL) {
        rc = MDB_INCOMPATIBLE;
        break;
      }
      if (mc->mc_ki[mc->mc_top] >= NUMKEYS(mc->mc_pg[mc->mc_top])) {
        mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top]);
        rc = MDB_NOTFOUND;
        break;
      }
      mc->mc_flags &= ~C_EOF;
      {
        MDB_node* leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);
        if (!F_ISSET(leaf->mn_flags, F_DUPDATA)) {
          MDB_GET_KEY(leaf, key);
          rc = mdb_node_read(mc, leaf, data);
          break;
        }
      }
      if (!(mc->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED)) {
        rc = EINVAL;
        break;
      }
      rc = mfunc(&mc->mc_xcursor->mx_cursor, data, NULL);
      break;
    case MDB_LAST:
      rc = mdb_cursor_last(mc, key, data);
      break;
    case MDB_LAST_DUP:
      mfunc = mdb_cursor_last;
      goto mmove;
    default:
      DPRINTF(("unhandled/unimplemented cursor operation %u", op));
      rc = EINVAL;
      break;
  }

  if (mc->mc_flags & C_DEL)
    mc->mc_flags ^= C_DEL;

  return rc;
}

/** Touch all the pages in the cursor stack. Set mc_top.
 *	Makes sure all the pages are writable, before attempting a write
 * operation.
 * @param[in] mc The cursor to operate on.
 */
static int mdb_cursor_touch(MDB_cursor* mc) {
  int rc = MDB_SUCCESS;

  if (mc->mc_dbi >= CORE_DBS && !(*mc->mc_dbflag & (DB_DIRTY | DB_DUPDATA))) {
    /* Touch DB record of named DB */
    MDB_cursor mc2;
    MDB_xcursor mcx;
    if (TXN_DBI_CHANGED(mc->mc_txn, mc->mc_dbi))
      return MDB_BAD_DBI;
    mdb_cursor_init(&mc2, mc->mc_txn, MAIN_DBI, &mcx);
    rc = mdb_page_search(&mc2, &mc->mc_dbx->md_name, MDB_PS_MODIFY);
    if (rc)
      return rc;
    *mc->mc_dbflag |= DB_DIRTY;
  }
  mc->mc_top = 0;
  if (mc->mc_snum) {
    do {
      rc = mdb_page_touch(mc);
    } while (!rc && ++(mc->mc_top) < mc->mc_snum);
    mc->mc_top = mc->mc_snum - 1;
  }
  return rc;
}

/** Do not spill pages to disk if txn is getting full, may fail instead */
#define MDB_NOSPILL 0x8000

static int _mdb_cursor_put(
    MDB_cursor* mc,
    MDB_val* key,
    MDB_val* data,
    unsigned int flags) {
  MDB_env* env;
  MDB_node* leaf = NULL;
  MDB_page *fp, *mp, *sub_root = NULL;
  uint16_t fp_flags;
  MDB_val xdata, *rdata, dkey, olddata;
  MDB_db dummy;
  int do_sub = 0, insert_key, insert_data;
  unsigned int mcount = 0, dcount = 0, nospill;
  size_t nsize;
  int rc, rc2;
  unsigned int nflags;
  DKBUF;

  if (mc == NULL || key == NULL)
    return EINVAL;

  env = mc->mc_txn->mt_env;

  /* Check this first so counter will always be zero on any
   * early failures.
   */
  if (flags & MDB_MULTIPLE) {
    dcount = data[1].mv_size;
    data[1].mv_size = 0;
    if (!F_ISSET(mc->mc_db->md_flags, MDB_DUPFIXED))
      return MDB_INCOMPATIBLE;
  }

  nospill = flags & MDB_NOSPILL;
  flags &= ~MDB_NOSPILL;

  if (mc->mc_txn->mt_flags & (MDB_TXN_RDONLY | MDB_TXN_BLOCKED))
    return (mc->mc_txn->mt_flags & MDB_TXN_RDONLY) ? EACCES : MDB_BAD_TXN;

  if (key->mv_size - 1 >= ENV_MAXKEY(env))
    return MDB_BAD_VALSIZE;

#if SIZE_MAX > MAXDATASIZE
  if (data->mv_size >
      ((mc->mc_db->md_flags & MDB_DUPSORT) ? ENV_MAXKEY(env) : MAXDATASIZE))
    return MDB_BAD_VALSIZE;
#else
  if ((mc->mc_db->md_flags & MDB_DUPSORT) && data->mv_size > ENV_MAXKEY(env))
    return MDB_BAD_VALSIZE;
#endif

  DPRINTF(
      ("==> put db %d key [%s], size %" Z "u, data size %" Z "u",
       DDBI(mc),
       DKEY(key),
       key ? key->mv_size : 0,
       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_db->md_root == P_INVALID) {
    /* new database, cursor has nothing to point to */
    mc->mc_snum = 0;
    mc->mc_top = 0;
    mc->mc_flags &= ~C_INITIALIZED;
    rc = MDB_NO_ROOT;
  } else {
    int exact = 0;
    MDB_val d2;
    if (flags & MDB_APPEND) {
      MDB_val k2;
      rc = mdb_cursor_last(mc, &k2, &d2);
      if (rc == 0) {
        rc = mc->mc_dbx->md_cmp(key, &k2);
        if (rc > 0) {
          rc = MDB_NOTFOUND;
          mc->mc_ki[mc->mc_top]++;
        } else {
          /* new key is <= last key */
          rc = MDB_KEYEXIST;
        }
      }
    } else {
      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;
  }

  if (mc->mc_flags & C_DEL)
    mc->mc_flags ^= C_DEL;

  /* Cursor is positioned, check for room in the dirty list */
  if (!nospill) {
    if (flags & MDB_MULTIPLE) {
      rdata = &xdata;
      xdata.mv_size = data->mv_size * dcount;
    } else {
      rdata = data;
    }
    if ((rc2 = mdb_page_spill(mc, key, rdata)))
      return rc2;
  }

  if (rc == MDB_NO_ROOT) {
    MDB_page* np;
    /* new database, write a root leaf page */
    DPUTS("allocating new root leaf page");
    if ((rc2 = mdb_page_new(mc, P_LEAF, 1, &np))) {
      return rc2;
    }
    mdb_cursor_push(mc, np);
    mc->mc_db->md_root = np->mp_pgno;
    mc->mc_db->md_depth++;
    *mc->mc_dbflag |= DB_DIRTY;
    if ((mc->mc_db->md_flags & (MDB_DUPSORT | MDB_DUPFIXED)) == MDB_DUPFIXED)
      MP_FLAGS(np) |= P_LEAF2;
    mc->mc_flags |= C_INITIALIZED;
  } else {
    /* make sure all cursor pages are writable */
    rc2 = mdb_cursor_touch(mc);
    if (rc2)
      return rc2;
  }

  insert_key = insert_data = rc;
  if (insert_key) {
    /* The key does not exist */
    DPRINTF(("inserting key at index %i", mc->mc_ki[mc->mc_top]));
    if ((mc->mc_db->md_flags & MDB_DUPSORT) &&
        LEAFSIZE(key, data) > env->me_nodemax) {
      /* Too big for a node, insert in sub-DB.  Set up an empty
       * "old sub-page" for prep_subDB to expand to a full page.
       */
      fp_flags = P_LEAF | P_DIRTY;
      fp = env->me_pbuf;
      fp->mp_pad = data->mv_size; /* used if MDB_DUPFIXED */
      MP_LOWER(fp) = MP_UPPER(fp) = (PAGEHDRSZ - PAGEBASE);
      olddata.mv_size = PAGEHDRSZ;
      goto prep_subDB;
    }
  } else {
    /* there's only a key anyway, so this is a no-op */
    if (IS_LEAF2(mc->mc_pg[mc->mc_top])) {
      char* ptr;
      unsigned int ksize = mc->mc_db->md_pad;
      if (key->mv_size != ksize)
        return MDB_BAD_VALSIZE;
      ptr = LEAF2KEY(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top], ksize);
      memcpy(ptr, key->mv_data, ksize);
    fix_parent:
      /* if overwriting slot 0 of leaf, need to
       * update branch key if there is a parent page
       */
      if (mc->mc_top && !mc->mc_ki[mc->mc_top]) {
        unsigned short dtop = 1;
        mc->mc_top--;
        /* slot 0 is always an empty key, find real slot */
        while (mc->mc_top && !mc->mc_ki[mc->mc_top]) {
          mc->mc_top--;
          dtop++;
        }
        if (mc->mc_ki[mc->mc_top])
          rc2 = mdb_update_key(mc, key);
        else
          rc2 = MDB_SUCCESS;
        mc->mc_top += dtop;
        if (rc2)
          return rc2;
      }
      return MDB_SUCCESS;
    }

  more:
    leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);
    olddata.mv_size = NODEDSZ(leaf);
    olddata.mv_data = NODEDATA(leaf);

    /* DB has dups? */
    if (F_ISSET(mc->mc_db->md_flags, MDB_DUPSORT)) {
      /* Prepare (sub-)page/sub-DB to accept the new item,
       * if needed.  fp: old sub-page or a header faking
       * it.  mp: new (sub-)page.  offset: growth in page
       * size.  xdata: node data with new page or DB.
       */
      unsigned i, offset = 0;
      mp = fp = xdata.mv_data = env->me_pbuf;
      mp->mp_pgno = mc->mc_pg[mc->mc_top]->mp_pgno;

      /* Was a single item before, must convert now */
      if (!F_ISSET(leaf->mn_flags, F_DUPDATA)) {
        MDB_cmp_func* dcmp;
        /* Just overwrite the current item */
        if (flags == MDB_CURRENT)
          goto current;
        dcmp = mc->mc_dbx->md_dcmp;
        if (NEED_CMP_CLONG(dcmp, olddata.mv_size))
          dcmp = mdb_cmp_clong;
        /* does data match? */
        if (!dcmp(data, &olddata)) {
          if (flags & (MDB_NODUPDATA | MDB_APPENDDUP))
            return MDB_KEYEXIST;
          /* overwrite it */
          goto current;
        }

        /* Back up original data item */
        dkey.mv_size = olddata.mv_size;
        dkey.mv_data = memcpy(fp + 1, olddata.mv_data, olddata.mv_size);

        /* Make sub-page header for the dup items, with dummy body */
        MP_FLAGS(fp) = P_LEAF | P_DIRTY | P_SUBP;
        MP_LOWER(fp) = (PAGEHDRSZ - PAGEBASE);
        xdata.mv_size = PAGEHDRSZ + dkey.mv_size + data->mv_size;
        if (mc->mc_db->md_flags & MDB_DUPFIXED) {
          MP_FLAGS(fp) |= P_LEAF2;
          fp->mp_pad = data->mv_size;
          xdata.mv_size += 2 * data->mv_size; /* leave space for 2 more */
        } else {
          xdata.mv_size += 2 * (sizeof(indx_t) + NODESIZE) +
              (dkey.mv_size & 1) + (data->mv_size & 1);
        }
        MP_UPPER(fp) = xdata.mv_size - PAGEBASE;
        olddata.mv_size = xdata.mv_size; /* pretend olddata is fp */
      } else if (leaf->mn_flags & F_SUBDATA) {
        /* Data is on sub-DB, just store it */
        flags |= F_DUPDATA | F_SUBDATA;
        goto put_sub;
      } else {
        /* Data is on sub-page */
        fp = olddata.mv_data;
        switch (flags) {
          default:
            if (!(mc->mc_db->md_flags & MDB_DUPFIXED)) {
              offset = EVEN(NODESIZE + sizeof(indx_t) + data->mv_size);
              break;
            }
            offset = fp->mp_pad;
            if (SIZELEFT(fp) < offset) {
              offset *= 4; /* space for 4 more */
              break;
            }
            /* FALLTHRU */ /* Big enough MDB_DUPFIXED sub-page */
          case MDB_CURRENT:
            MP_FLAGS(fp) |= P_DIRTY;
            COPY_PGNO(MP_PGNO(fp), MP_PGNO(mp));
            mc->mc_xcursor->mx_cursor.mc_pg[0] = fp;
            flags |= F_DUPDATA;
            goto put_sub;
        }
        xdata.mv_size = olddata.mv_size + offset;
      }

      fp_flags = MP_FLAGS(fp);
      if (NODESIZE + NODEKSZ(leaf) + xdata.mv_size > env->me_nodemax) {
        /* Too big for a sub-page, convert to sub-DB */
        fp_flags &= ~P_SUBP;
      prep_subDB:
        if (mc->mc_db->md_flags & MDB_DUPFIXED) {
          fp_flags |= P_LEAF2;
          dummy.md_pad = fp->mp_pad;
          dummy.md_flags = MDB_DUPFIXED;
          if (mc->mc_db->md_flags & MDB_INTEGERDUP)
            dummy.md_flags |= MDB_INTEGERKEY;
        } else {
          dummy.md_pad = 0;
          dummy.md_flags = 0;
        }
        dummy.md_depth = 1;
        dummy.md_branch_pages = 0;
        dummy.md_leaf_pages = 1;
        dummy.md_overflow_pages = 0;
        dummy.md_entries = NUMKEYS(fp);
        xdata.mv_size = sizeof(MDB_db);
        xdata.mv_data = &dummy;
        if ((rc = mdb_page_alloc(mc, 1, &mp)))
          return rc;
        offset = env->me_psize - olddata.mv_size;
        flags |= F_DUPDATA | F_SUBDATA;
        dummy.md_root = mp->mp_pgno;
        sub_root = mp;
      }
      if (mp != fp) {
        MP_FLAGS(mp) = fp_flags | P_DIRTY;
        MP_PAD(mp) = MP_PAD(fp);
        MP_LOWER(mp) = MP_LOWER(fp);
        MP_UPPER(mp) = MP_UPPER(fp) + offset;
        if (fp_flags & P_LEAF2) {
          memcpy(METADATA(mp), METADATA(fp), NUMKEYS(fp) * fp->mp_pad);
        } else {
          memcpy(
              (char*)mp + MP_UPPER(mp) + PAGEBASE,
              (char*)fp + MP_UPPER(fp) + PAGEBASE,
              olddata.mv_size - MP_UPPER(fp) - PAGEBASE);
          memcpy(
              (char*)MP_PTRS(mp),
              (char*)MP_PTRS(fp),
              NUMKEYS(fp) * sizeof(mp->mp_ptrs[0]));
          for (i = 0; i < NUMKEYS(fp); i++)
            mp->mp_ptrs[i] += offset;
        }
      }

      rdata = &xdata;
      flags |= F_DUPDATA;
      do_sub = 1;
      if (!insert_key)
        mdb_node_del(mc, 0);
      goto new_sub;
    }
  current:
    /* LMDB passes F_SUBDATA in 'flags' to write a DB record */
    if ((leaf->mn_flags ^ flags) & F_SUBDATA)
      return MDB_INCOMPATIBLE;
    /* overflow page overwrites need special handling */
    if (F_ISSET(leaf->mn_flags, F_BIGDATA)) {
      MDB_page* omp;
      pgno_t pg;
      int level, ovpages, dpages = OVPAGES(data->mv_size, env->me_psize);

      memcpy(&pg, olddata.mv_data, sizeof(pg));
      if ((rc2 = mdb_page_get(mc, pg, &omp, &level)) != 0)
        return rc2;
      ovpages = omp->mp_pages;

      /* Is the ov page large enough? */
      if (ovpages >= dpages) {
        if (!(omp->mp_flags & P_DIRTY) &&
            (level || (env->me_flags & MDB_WRITEMAP))) {
          rc = mdb_page_unspill(mc->mc_txn, omp, &omp);
          if (rc)
            return rc;
          level = 0; /* dirty in this txn or clean */
        }
        /* Is it dirty? */
        if (omp->mp_flags & P_DIRTY) {
          /* yes, overwrite it. Note in this case we don't
           * bother to try shrinking the page if the new data
           * is smaller than the overflow threshold.
           */
          if (level > 1) {
            /* It is writable only in a parent txn */
            size_t sz = (size_t)env->me_psize * ovpages, off;
            MDB_page* np = mdb_page_malloc(mc->mc_txn, ovpages);
            MDB_ID2 id2;
            if (!np)
              return ENOMEM;
            id2.mid = pg;
            id2.mptr = np;
            /* Note - this page is already counted in parent's dirty_room */
            rc2 = mdb_mid2l_insert(mc->mc_txn->mt_u.dirty_list, &id2);
            mdb_cassert(mc, rc2 == 0);
            /* Currently we make the page look as with put() in the
             * parent txn, in case the user peeks at MDB_RESERVEd
             * or unused parts. Some users treat ovpages specially.
             */
            if (!(flags & MDB_RESERVE)) {
              /* Skip the part where LMDB will put *data.
               * Copy end of page, adjusting alignment so
               * compiler may copy words instead of bytes.
               */
              off = (PAGEHDRSZ + data->mv_size) & -(int)sizeof(size_t);
              memcpy(
                  (size_t*)((char*)np + off),
                  (size_t*)((char*)omp + off),
                  sz - off);
              sz = PAGEHDRSZ;
            }
            memcpy(np, omp, sz); /* Copy beginning of page */
            omp = np;
          }
          SETDSZ(leaf, data->mv_size);
          if (F_ISSET(flags, MDB_RESERVE))
            data->mv_data = METADATA(omp);
          else
            memcpy(METADATA(omp), data->mv_data, data->mv_size);
          return MDB_SUCCESS;
        }
      }
      if ((rc2 = mdb_ovpage_free(mc, omp)) != MDB_SUCCESS)
        return rc2;
    } else if (data->mv_size == olddata.mv_size) {
      /* same size, just replace it. Note that we could
       * also reuse this node if the new data is smaller,
       * but instead we opt to shrink the node in that case.
       */
      if (F_ISSET(flags, MDB_RESERVE))
        data->mv_data = olddata.mv_data;
      else if (!(mc->mc_flags & C_SUB))
        memcpy(olddata.mv_data, data->mv_data, data->mv_size);
      else {
        if (key->mv_size != NODEKSZ(leaf))
          goto new_ksize;
        memcpy(NODEKEY(leaf), key->mv_data, key->mv_size);
        goto fix_parent;
      }
      return MDB_SUCCESS;
    }
  new_ksize:
    mdb_node_del(mc, 0);
  }

  rdata = data;

new_sub:
  nflags = flags & NODE_ADD_FLAGS;
  nsize = IS_LEAF2(mc->mc_pg[mc->mc_top]) ? key->mv_size
                                          : mdb_leaf_size(env, key, rdata);
  if (SIZELEFT(mc->mc_pg[mc->mc_top]) < nsize) {
    if ((flags & (F_DUPDATA | F_SUBDATA)) == F_DUPDATA)
      nflags &= ~MDB_APPEND; /* sub-page may need room to grow */
    if (!insert_key)
      nflags |= MDB_SPLIT_REPLACE;
    rc = mdb_page_split(mc, key, rdata, P_INVALID, nflags);
  } else {
    /* There is room already in this leaf page. */
    rc = mdb_node_add(mc, mc->mc_ki[mc->mc_top], key, rdata, 0, nflags);
    if (rc == 0) {
      /* Adjust other cursors pointing to mp */
      MDB_cursor *m2, *m3;
      MDB_dbi dbi = mc->mc_dbi;
      unsigned i = mc->mc_top;
      MDB_page* mp = mc->mc_pg[i];

      for (m2 = mc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
        if (mc->mc_flags & C_SUB)
          m3 = &m2->mc_xcursor->mx_cursor;
        else
          m3 = m2;
        if (m3 == mc || m3->mc_snum < mc->mc_snum || m3->mc_pg[i] != mp)
          continue;
        if (m3->mc_ki[i] >= mc->mc_ki[i] && insert_key) {
          m3->mc_ki[i]++;
        }
        XCURSOR_REFRESH(m3, i, mp);
      }
    }
  }

  if (rc == MDB_SUCCESS) {
    /* 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) {
      int xflags, new_dupdata;
      mdb_size_t ecount;
    put_sub:
      xdata.mv_size = 0;
      xdata.mv_data = "";
      leaf = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);
      if ((flags & (MDB_CURRENT | MDB_APPENDDUP)) == MDB_CURRENT) {
        xflags = MDB_CURRENT | MDB_NOSPILL;
      } else {
        mdb_xcursor_init1(mc, leaf);
        xflags = (flags & MDB_NODUPDATA) ? MDB_NOOVERWRITE | MDB_NOSPILL
                                         : MDB_NOSPILL;
      }
      if (sub_root)
        mc->mc_xcursor->mx_cursor.mc_pg[0] = sub_root;
      new_dupdata = (int)dkey.mv_size;
      /* converted, write the original data first */
      if (dkey.mv_size) {
        rc = _mdb_cursor_put(&mc->mc_xcursor->mx_cursor, &dkey, &xdata, xflags);
        if (rc)
          goto bad_sub;
        /* we've done our job */
        dkey.mv_size = 0;
      }
      if (!(leaf->mn_flags & F_SUBDATA) || sub_root) {
        /* Adjust other cursors pointing to mp */
        MDB_cursor* m2;
        MDB_xcursor* mx = mc->mc_xcursor;
        unsigned i = mc->mc_top;
        MDB_page* mp = mc->mc_pg[i];

        for (m2 = mc->mc_txn->mt_cursors[mc->mc_dbi]; m2; m2 = m2->mc_next) {
          if (m2 == mc || m2->mc_snum < mc->mc_snum)
            continue;
          if (!(m2->mc_flags & C_INITIALIZED))
            continue;
          if (m2->mc_pg[i] == mp) {
            if (m2->mc_ki[i] == mc->mc_ki[i]) {
              mdb_xcursor_init2(m2, mx, new_dupdata);
            } else if (!insert_key) {
              XCURSOR_REFRESH(m2, i, mp);
            }
          }
        }
      }
      ecount = mc->mc_xcursor->mx_db.md_entries;
      if (flags & MDB_APPENDDUP)
        xflags |= MDB_APPEND;
      rc = _mdb_cursor_put(&mc->mc_xcursor->mx_cursor, data, &xdata, xflags);
      if (flags & F_SUBDATA) {
        void* db = NODEDATA(leaf);
        memcpy(db, &mc->mc_xcursor->mx_db, sizeof(MDB_db));
      }
      insert_data = mc->mc_xcursor->mx_db.md_entries - ecount;
    }
    /* Increment count unless we just replaced an existing item. */
    if (insert_data)
      mc->mc_db->md_entries++;
    if (insert_key) {
      /* Invalidate txn if we created an empty sub-DB */
      if (rc)
        goto bad_sub;
      /* If we succeeded and the key didn't exist before,
       * make sure the cursor is marked valid.
       */
      mc->mc_flags |= C_INITIALIZED;
    }
    if (flags & MDB_MULTIPLE) {
      if (!rc) {
        mcount++;
        /* let caller know how many succeeded, if any */
        data[1].mv_size = mcount;
        if (mcount < dcount) {
          data[0].mv_data = (char*)data[0].mv_data + data[0].mv_size;
          insert_key = insert_data = 0;
          goto more;
        }
      }
    }
    return rc;
  bad_sub:
    if (rc == MDB_KEYEXIST) /* should not happen, we deleted that item */
      rc = MDB_PROBLEM;
  }
  mc->mc_txn->mt_flags |= MDB_TXN_ERROR;
  return rc;
}

int mdb_cursor_put(
    MDB_cursor* mc,
    MDB_val* key,
    MDB_val* data,
    unsigned int flags) {
  DKBUF;
  DDBUF;
  int rc = _mdb_cursor_put(mc, key, data, flags);
  MDB_TRACE(
      ("%p, %" Z "u[%s], %" Z "u%s, %u",
       mc,
       key ? key->mv_size : 0,
       DKEY(key),
       data ? data->mv_size : 0,
       data ? mdb_dval(mc->mc_txn, mc->mc_dbi, data, dbuf) : "",
       flags));
  return rc;
}

static int _mdb_cursor_del(MDB_cursor* mc, unsigned int flags) {
  MDB_node* leaf;
  MDB_page* mp;
  int rc;

  if (mc->mc_txn->mt_flags & (MDB_TXN_RDONLY | MDB_TXN_BLOCKED))
    return (mc->mc_txn->mt_flags & MDB_TXN_RDONLY) ? EACCES : MDB_BAD_TXN;

  if (!(mc->mc_flags & C_INITIALIZED))
    return EINVAL;

  if (mc->mc_ki[mc->mc_top] >= NUMKEYS(mc->mc_pg[mc->mc_top]))
    return MDB_NOTFOUND;

  if (!(flags & MDB_NOSPILL) && (rc = mdb_page_spill(mc, NULL, NULL)))
    return rc;

  rc = mdb_cursor_touch(mc);
  if (rc)
    return rc;

  mp = mc->mc_pg[mc->mc_top];
  if (!IS_LEAF(mp))
    return MDB_CORRUPTED;
  if (IS_LEAF2(mp))
    goto del_key;
  leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]);

  if (F_ISSET(leaf->mn_flags, F_DUPDATA)) {
    if (flags & MDB_NODUPDATA) {
      /* mdb_cursor_del0() will subtract the final entry */
      mc->mc_db->md_entries -= mc->mc_xcursor->mx_db.md_entries - 1;
      mc->mc_xcursor->mx_cursor.mc_flags &= ~C_INITIALIZED;
    } else {
      if (!F_ISSET(leaf->mn_flags, F_SUBDATA)) {
        mc->mc_xcursor->mx_cursor.mc_pg[0] = NODEDATA(leaf);
      }
      rc = _mdb_cursor_del(&mc->mc_xcursor->mx_cursor, MDB_NOSPILL);
      if (rc)
        return rc;
      /* If sub-DB still has entries, we're done */
      if (mc->mc_xcursor->mx_db.md_entries) {
        if (leaf->mn_flags & F_SUBDATA) {
          /* update subDB info */
          void* db = NODEDATA(leaf);
          memcpy(db, &mc->mc_xcursor->mx_db, sizeof(MDB_db));
        } else {
          MDB_cursor* m2;
          /* shrink fake page */
          mdb_node_shrink(mp, mc->mc_ki[mc->mc_top]);
          leaf = NODEPTR(mp, mc->mc_ki[mc->mc_top]);
          mc->mc_xcursor->mx_cursor.mc_pg[0] = NODEDATA(leaf);
          /* fix other sub-DB cursors pointed at fake pages on this page */
          for (m2 = mc->mc_txn->mt_cursors[mc->mc_dbi]; m2; m2 = m2->mc_next) {
            if (m2 == mc || m2->mc_snum < mc->mc_snum)
              continue;
            if (!(m2->mc_flags & C_INITIALIZED))
              continue;
            if (m2->mc_pg[mc->mc_top] == mp) {
              XCURSOR_REFRESH(m2, mc->mc_top, mp);
            }
          }
        }
        mc->mc_db->md_entries--;
        return rc;
      } else {
        mc->mc_xcursor->mx_cursor.mc_flags &= ~C_INITIALIZED;
      }
      /* otherwise fall thru and delete the sub-DB */
    }

    if (leaf->mn_flags & F_SUBDATA) {
      /* add all the child DB's pages to the free list */
      rc = mdb_drop0(&mc->mc_xcursor->mx_cursor, 0);
      if (rc)
        goto fail;
    }
  }
  /* LMDB passes F_SUBDATA in 'flags' to delete a DB record */
  else if ((leaf->mn_flags ^ flags) & F_SUBDATA) {
    rc = MDB_INCOMPATIBLE;
    goto fail;
  }

  /* add overflow pages to free list */
  if (F_ISSET(leaf->mn_flags, F_BIGDATA)) {
    MDB_page* omp;
    pgno_t pg;

    memcpy(&pg, NODEDATA(leaf), sizeof(pg));
    if ((rc = mdb_page_get(mc, pg, &omp, NULL)) ||
        (rc = mdb_ovpage_free(mc, omp)))
      goto fail;
  }

del_key:
  return mdb_cursor_del0(mc);

fail:
  mc->mc_txn->mt_flags |= MDB_TXN_ERROR;
  return rc;
}

int mdb_cursor_del(MDB_cursor* mc, unsigned int flags) {
  MDB_TRACE(("%p, %u", mc, flags));
  return _mdb_cursor_del(mc, flags);
}

/** Allocate and initialize new pages for a database.
 * Set #MDB_TXN_ERROR on failure.
 * @param[in] mc a cursor on the database being added to.
 * @param[in] flags flags defining what type of page is being allocated.
 * @param[in] num the number of pages to allocate. This is usually 1,
 * unless allocating overflow pages for a large record.
 * @param[out] mp Address of a page, or NULL on failure.
 * @return 0 on success, non-zero on failure.
 */
static int
mdb_page_new(MDB_cursor* mc, uint32_t flags, int num, MDB_page** mp) {
  MDB_page* np;
  int rc;

  if ((rc = mdb_page_alloc(mc, num, &np)))
    return rc;
  DPRINTF(
      ("allocated new mpage %" Yu ", page size %u",
       np->mp_pgno,
       mc->mc_txn->mt_env->me_psize));
  np->mp_flags = flags | P_DIRTY;
  np->mp_lower = (PAGEHDRSZ - PAGEBASE);
  np->mp_upper = mc->mc_txn->mt_env->me_psize - PAGEBASE;

  if (IS_BRANCH(np))
    mc->mc_db->md_branch_pages++;
  else if (IS_LEAF(np))
    mc->mc_db->md_leaf_pages++;
  else if (IS_OVERFLOW(np)) {
    mc->mc_db->md_overflow_pages += num;
    np->mp_pages = num;
  }
  *mp = np;

  return 0;
}

/** Calculate the size of a leaf node.
 * The size depends on the environment's page size; if a data item
 * is too large it will be put onto an overflow page and the node
 * size will only include the key and not the data. Sizes are always
 * rounded up to an even number of bytes, to guarantee 2-byte alignment
 * of the #MDB_node headers.
 * @param[in] env The environment handle.
 * @param[in] key The key for the node.
 * @param[in] data The data for the node.
 * @return The number of bytes needed to store the node.
 */
static size_t mdb_leaf_size(MDB_env* env, MDB_val* key, MDB_val* data) {
  size_t sz;

  sz = LEAFSIZE(key, data);
  if (sz > env->me_nodemax) {
    /* put on overflow page */
    sz -= data->mv_size - sizeof(pgno_t);
  }

  return EVEN(sz + sizeof(indx_t));
}

/** Calculate the size of a branch node.
 * The size should depend on the environment's page size but since
 * we currently don't support spilling large keys onto overflow
 * pages, it's simply the size of the #MDB_node header plus the
 * size of the key. Sizes are always rounded up to an even number
 * of bytes, to guarantee 2-byte alignment of the #MDB_node headers.
 * @param[in] env The environment handle.
 * @param[in] key The key for the node.
 * @return The number of bytes needed to store the node.
 */
static size_t mdb_branch_size(MDB_env* env, MDB_val* key) {
  size_t sz;

  sz = INDXSIZE(key);
  if (sz > env->me_nodemax) {
    /* put on overflow page */
    /* not implemented */
    /* sz -= key->size - sizeof(pgno_t); */
  }

  return sz + sizeof(indx_t);
}

/** Add a node to the page pointed to by the cursor.
 * Set #MDB_TXN_ERROR on failure.
 * @param[in] mc The cursor for this operation.
 * @param[in] indx The index on the page where the new node should be added.
 * @param[in] key The key for the new node.
 * @param[in] data The data for the new node, if any.
 * @param[in] pgno The page number, if adding a branch node.
 * @param[in] flags Flags for the node.
 * @return 0 on success, non-zero on failure. Possible errors are:
 * <ul>
 *	<li>ENOMEM - failed to allocate overflow pages for the node.
 *	<li>MDB_PAGE_FULL - there is insufficient room in the page. This error
 *	should never happen since all callers already calculate the
 *	page's free space before calling this function.
 * </ul>
 */
static int mdb_node_add(
    MDB_cursor* mc,
    indx_t indx,
    MDB_val* key,
    MDB_val* data,
    pgno_t pgno,
    unsigned int flags) {
  unsigned int i;
  size_t node_size = NODESIZE;
  ssize_t room;
  indx_t ofs;
  MDB_node* node;
  MDB_page* mp = mc->mc_pg[mc->mc_top];
  MDB_page* ofp = NULL; /* overflow page */
  void* ndata;
  DKBUF;

  mdb_cassert(mc, MP_UPPER(mp) >= MP_LOWER(mp));

  DPRINTF(
      ("add to %s %spage %" Yu " index %i, data size %" Z "u key size %" Z
       "u [%s]",
       IS_LEAF(mp) ? "leaf" : "branch",
       IS_SUBP(mp) ? "sub-" : "",
       mdb_dbg_pgno(mp),
       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_db->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_LOWER(mp) += sizeof(indx_t);
    MP_UPPER(mp) -= ksize - sizeof(indx_t);
    return MDB_SUCCESS;
  }

  room = (ssize_t)SIZELEFT(mp) - (ssize_t)sizeof(indx_t);
  if (key != NULL)
    node_size += key->mv_size;
  if (IS_LEAF(mp)) {
    mdb_cassert(mc, key && data);
    if (F_ISSET(flags, F_BIGDATA)) {
      /* Data already on overflow page. */
      node_size += sizeof(pgno_t);
    } else if (node_size + data->mv_size > mc->mc_txn->mt_env->me_nodemax) {
      int ovpages = OVPAGES(data->mv_size, mc->mc_txn->mt_env->me_psize);
      int rc;
      /* Put data on overflow page. */
      DPRINTF(
          ("data size is %" Z "u, node would be %" Z
           "u, put data on overflow page",
           data->mv_size,
           node_size + data->mv_size));
      node_size = EVEN(node_size + sizeof(pgno_t));
      if ((ssize_t)node_size > room)
        goto full;
      if ((rc = mdb_page_new(mc, P_OVERFLOW, ovpages, &ofp)))
        return rc;
      DPRINTF(("allocated overflow page %" Yu, ofp->mp_pgno));
      flags |= F_BIGDATA;
      goto update;
    } else {
      node_size += data->mv_size;
    }
  }
  node_size = EVEN(node_size);
  if ((ssize_t)node_size > room)
    goto full;

update:
  /* Move higher pointers up one slot. */
  for (i = NUMKEYS(mp); i > indx; i--)
    MP_PTRS(mp)[i] = MP_PTRS(mp)[i - 1];

  /* Adjust free space offsets. */
  ofs = MP_UPPER(mp) - node_size;
  mdb_cassert(mc, ofs >= MP_LOWER(mp) + sizeof(indx_t));
  MP_PTRS(mp)[indx] = ofs;
  MP_UPPER(mp) = ofs;
  MP_LOWER(mp) += 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)) {
    ndata = NODEDATA(node);
    if (ofp == NULL) {
      if (F_ISSET(flags, F_BIGDATA))
        memcpy(ndata, data->mv_data, sizeof(pgno_t));
      else if (F_ISSET(flags, MDB_RESERVE))
        data->mv_data = ndata;
      else
        memcpy(ndata, data->mv_data, data->mv_size);
    } else {
      memcpy(ndata, &ofp->mp_pgno, sizeof(pgno_t));
      ndata = METADATA(ofp);
      if (F_ISSET(flags, MDB_RESERVE))
        data->mv_data = ndata;
      else
        memcpy(ndata, data->mv_data, data->mv_size);
    }
  }

  return MDB_SUCCESS;

full:
  DPRINTF(
      ("not enough room in page %" Yu ", got %u ptrs",
       mdb_dbg_pgno(mp),
       NUMKEYS(mp)));
  DPRINTF(
      ("upper-lower = %u - %u = %" Z "d", MP_UPPER(mp), MP_LOWER(mp), room));
  DPRINTF(("node size = %" Z "u", node_size));
  mc->mc_txn->mt_flags |= MDB_TXN_ERROR;
  return MDB_PAGE_FULL;
}

/** Delete the specified node from a page.
 * @param[in] mc Cursor pointing to the node to delete.
 * @param[in] ksize The size of a node. Only used if the page is
 * part of a #MDB_DUPFIXED database.
 */
static void mdb_node_del(MDB_cursor* mc, int ksize) {
  MDB_page* mp = mc->mc_pg[mc->mc_top];
  indx_t indx = mc->mc_ki[mc->mc_top];
  unsigned int sz;
  indx_t i, j, numkeys, ptr;
  MDB_node* node;
  char* base;

  DPRINTF(
      ("delete node %u on %s page %" Yu,
       indx,
       IS_LEAF(mp) ? "leaf" : "branch",
       mdb_dbg_pgno(mp)));
  numkeys = NUMKEYS(mp);
  mdb_cassert(mc, indx < numkeys);

  if (IS_LEAF2(mp)) {
    int x = numkeys - 1 - indx;
    base = LEAF2KEY(mp, indx, ksize);
    if (x)
      memmove(base, base + ksize, x * ksize);
    MP_LOWER(mp) -= sizeof(indx_t);
    MP_UPPER(mp) += 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 = EVEN(sz);

  ptr = MP_PTRS(mp)[indx];
  for (i = j = 0; i < numkeys; i++) {
    if (i != indx) {
      MP_PTRS(mp)[j] = MP_PTRS(mp)[i];
      if (MP_PTRS(mp)[i] < ptr)
        MP_PTRS(mp)[j] += sz;
      j++;
    }
  }

  base = (char*)mp + MP_UPPER(mp) + PAGEBASE;
  memmove(base + sz, base, ptr - MP_UPPER(mp));

  MP_LOWER(mp) -= sizeof(indx_t);
  MP_UPPER(mp) += sz;
}

/** Compact the main page after deleting a node on a subpage.
 * @param[in] mp The main page to operate on.
 * @param[in] indx The index of the subpage on the main page.
 */
static void mdb_node_shrink(MDB_page* mp, indx_t indx) {
  MDB_node* node;
  MDB_page *sp, *xp;
  char* base;
  indx_t delta, nsize, len, ptr;
  int i;

  node = NODEPTR(mp, indx);
  sp = (MDB_page*)NODEDATA(node);
  delta = SIZELEFT(sp);
  nsize = NODEDSZ(node) - delta;

  /* Prepare to shift upward, set len = length(subpage part to shift) */
  if (IS_LEAF2(sp)) {
    len = nsize;
    if (nsize & 1)
      return; /* do not make the node uneven-sized */
  } else {
    xp = (MDB_page*)((char*)sp + delta); /* destination subpage */
    for (i = NUMKEYS(sp); --i >= 0;)
      MP_PTRS(xp)[i] = MP_PTRS(sp)[i] - delta;
    len = PAGEHDRSZ;
  }
  MP_UPPER(sp) = MP_LOWER(sp);
  COPY_PGNO(MP_PGNO(sp), mp->mp_pgno);
  SETDSZ(node, nsize);

  /* Shift <lower nodes...initial part of subpage> upward */
  base = (char*)mp + mp->mp_upper + PAGEBASE;
  memmove(base + delta, base, (char*)sp + len - base);

  ptr = mp->mp_ptrs[indx];
  for (i = NUMKEYS(mp); --i >= 0;) {
    if (mp->mp_ptrs[i] <= ptr)
      mp->mp_ptrs[i] += delta;
  }
  mp->mp_upper += delta;
}

/** Initial setup of a sorted-dups cursor.
 * Sorted duplicates are implemented as a sub-database for the given key.
 * The duplicate data items are actually keys of the sub-database.
 * Operations on the duplicate data items are performed using a sub-cursor
 * initialized when the sub-database is first accessed. This function does
 * the preliminary setup of the sub-cursor, filling in the fields that
 * depend only on the parent DB.
 * @param[in] mc The main cursor whose sorted-dups cursor is to be initialized.
 */
static void mdb_xcursor_init0(MDB_cursor* mc) {
  MDB_xcursor* mx = mc->mc_xcursor;

  mx->mx_cursor.mc_xcursor = NULL;
  mx->mx_cursor.mc_txn = mc->mc_txn;
  mx->mx_cursor.mc_db = &mx->mx_db;
  mx->mx_cursor.mc_dbx = &mx->mx_dbx;
  mx->mx_cursor.mc_dbi = mc->mc_dbi;
  mx->mx_cursor.mc_dbflag = &mx->mx_dbflag;
  mx->mx_cursor.mc_snum = 0;
  mx->mx_cursor.mc_top = 0;
  MC_SET_OVPG(&mx->mx_cursor, NULL);
  mx->mx_cursor.mc_flags =
      C_SUB | (mc->mc_flags & (C_ORIG_RDONLY | C_WRITEMAP));
  mx->mx_dbx.md_name.mv_size = 0;
  mx->mx_dbx.md_name.mv_data = NULL;
  mx->mx_dbx.md_cmp = mc->mc_dbx->md_dcmp;
  mx->mx_dbx.md_dcmp = NULL;
  mx->mx_dbx.md_rel = mc->mc_dbx->md_rel;
}

/** Final setup of a sorted-dups cursor.
 *	Sets up the fields that depend on the data from the main cursor.
 * @param[in] mc The main cursor whose sorted-dups cursor is to be initialized.
 * @param[in] node The data containing the #MDB_db record for the
 * sorted-dup database.
 */
static void mdb_xcursor_init1(MDB_cursor* mc, MDB_node* node) {
  MDB_xcursor* mx = mc->mc_xcursor;

  mx->mx_cursor.mc_flags &= C_SUB | C_ORIG_RDONLY | C_WRITEMAP;
  if (node->mn_flags & F_SUBDATA) {
    memcpy(&mx->mx_db, NODEDATA(node), sizeof(MDB_db));
    mx->mx_cursor.mc_pg[0] = 0;
    mx->mx_cursor.mc_snum = 0;
    mx->mx_cursor.mc_top = 0;
  } else {
    MDB_page* fp = NODEDATA(node);
    mx->mx_db.md_pad = 0;
    mx->mx_db.md_flags = 0;
    mx->mx_db.md_depth = 1;
    mx->mx_db.md_branch_pages = 0;
    mx->mx_db.md_leaf_pages = 1;
    mx->mx_db.md_overflow_pages = 0;
    mx->mx_db.md_entries = NUMKEYS(fp);
    COPY_PGNO(mx->mx_db.md_root, MP_PGNO(fp));
    mx->mx_cursor.mc_snum = 1;
    mx->mx_cursor.mc_top = 0;
    mx->mx_cursor.mc_flags |= C_INITIALIZED;
    mx->mx_cursor.mc_pg[0] = fp;
    mx->mx_cursor.mc_ki[0] = 0;
    if (mc->mc_db->md_flags & MDB_DUPFIXED) {
      mx->mx_db.md_flags = MDB_DUPFIXED;
      mx->mx_db.md_pad = fp->mp_pad;
      if (mc->mc_db->md_flags & MDB_INTEGERDUP)
        mx->mx_db.md_flags |= MDB_INTEGERKEY;
    }
  }
  DPRINTF(
      ("Sub-db -%u root page %" Yu, mx->mx_cursor.mc_dbi, mx->mx_db.md_root));
  mx->mx_dbflag = DB_VALID | DB_USRVALID | DB_DUPDATA;
  if (NEED_CMP_CLONG(mx->mx_dbx.md_cmp, mx->mx_db.md_pad))
    mx->mx_dbx.md_cmp = mdb_cmp_clong;
}

/** Fixup a sorted-dups cursor due to underlying update.
 *	Sets up some fields that depend on the data from the main cursor.
 *	Almost the same as init1, but skips initialization steps if the
 *	xcursor had already been used.
 * @param[in] mc The main cursor whose sorted-dups cursor is to be fixed up.
 * @param[in] src_mx The xcursor of an up-to-date cursor.
 * @param[in] new_dupdata True if converting from a non-#F_DUPDATA item.
 */
static void
mdb_xcursor_init2(MDB_cursor* mc, MDB_xcursor* src_mx, int new_dupdata) {
  MDB_xcursor* mx = mc->mc_xcursor;

  if (new_dupdata) {
    mx->mx_cursor.mc_snum = 1;
    mx->mx_cursor.mc_top = 0;
    mx->mx_cursor.mc_flags |= C_INITIALIZED;
    mx->mx_cursor.mc_ki[0] = 0;
    mx->mx_dbflag = DB_VALID | DB_USRVALID | DB_DUPDATA;
#if UINT_MAX < MDB_SIZE_MAX /* matches mdb_xcursor_init1:NEED_CMP_CLONG() */
    mx->mx_dbx.md_cmp = src_mx->mx_dbx.md_cmp;
#endif
  } else if (!(mx->mx_cursor.mc_flags & C_INITIALIZED)) {
    return;
  }
  mx->mx_db = src_mx->mx_db;
  mx->mx_cursor.mc_pg[0] = src_mx->mx_cursor.mc_pg[0];
  DPRINTF(
      ("Sub-db -%u root page %" Yu, mx->mx_cursor.mc_dbi, mx->mx_db.md_root));
}

/** Initialize a cursor for a given transaction and database. */
static void
mdb_cursor_init(MDB_cursor* mc, MDB_txn* txn, MDB_dbi dbi, MDB_xcursor* mx) {
  mc->mc_next = NULL;
  mc->mc_backup = NULL;
  mc->mc_dbi = dbi;
  mc->mc_txn = txn;
  mc->mc_db = &txn->mt_dbs[dbi];
  mc->mc_dbx = &txn->mt_dbxs[dbi];
  mc->mc_dbflag = &txn->mt_dbflags[dbi];
  mc->mc_snum = 0;
  mc->mc_top = 0;
  mc->mc_pg[0] = 0;
  mc->mc_ki[0] = 0;
  MC_SET_OVPG(mc, NULL);
  mc->mc_flags = txn->mt_flags & (C_ORIG_RDONLY | C_WRITEMAP);
  if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT) {
    mdb_tassert(txn, mx != NULL);
    mc->mc_xcursor = mx;
    mdb_xcursor_init0(mc);
  } else {
    mc->mc_xcursor = NULL;
  }
  if (*mc->mc_dbflag & DB_STALE) {
    mdb_page_search(mc, NULL, MDB_PS_ROOTONLY);
  }
}

int mdb_cursor_open(MDB_txn* txn, MDB_dbi dbi, MDB_cursor** ret) {
  MDB_cursor* mc;
  size_t size = sizeof(MDB_cursor);

  if (!ret || !TXN_DBI_EXIST(txn, dbi, DB_VALID))
    return EINVAL;

  if (txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  if (dbi == FREE_DBI && !F_ISSET(txn->mt_flags, MDB_TXN_RDONLY))
    return EINVAL;

  if (txn->mt_dbs[dbi].md_flags & MDB_DUPSORT)
    size += sizeof(MDB_xcursor);

  if ((mc = malloc(size)) != NULL) {
    mdb_cursor_init(mc, txn, dbi, (MDB_xcursor*)(mc + 1));
    if (txn->mt_cursors) {
      mc->mc_next = txn->mt_cursors[dbi];
      txn->mt_cursors[dbi] = mc;
      mc->mc_flags |= C_UNTRACK;
    }
  } else {
    return ENOMEM;
  }

  MDB_TRACE(("%p, %u = %p", txn, dbi, mc));
  *ret = mc;

  return MDB_SUCCESS;
}

int mdb_cursor_renew(MDB_txn* txn, MDB_cursor* mc) {
  if (!mc || !TXN_DBI_EXIST(txn, mc->mc_dbi, DB_VALID))
    return EINVAL;

  if ((mc->mc_flags & C_UNTRACK) || txn->mt_cursors)
    return EINVAL;

  if (txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  mdb_cursor_init(mc, txn, mc->mc_dbi, mc->mc_xcursor);
  return MDB_SUCCESS;
}

/* Return the count of duplicate data items for the current key */
int mdb_cursor_count(MDB_cursor* mc, mdb_size_t* countp) {
  MDB_node* leaf;

  if (mc == NULL || countp == NULL)
    return EINVAL;

  if (mc->mc_xcursor == NULL)
    return MDB_INCOMPATIBLE;

  if (mc->mc_txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  if (!(mc->mc_flags & C_INITIALIZED))
    return EINVAL;

  if (!mc->mc_snum)
    return MDB_NOTFOUND;

  if (mc->mc_flags & C_EOF) {
    if (mc->mc_ki[mc->mc_top] >= NUMKEYS(mc->mc_pg[mc->mc_top]))
      return MDB_NOTFOUND;
    mc->mc_flags ^= C_EOF;
  }

  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_db.md_entries;
  }
  return MDB_SUCCESS;
}

void mdb_cursor_close(MDB_cursor* mc) {
  MDB_TRACE(("%p", mc));
  if (mc) {
    MDB_CURSOR_UNREF(mc, 0);
  }
  if (mc && !mc->mc_backup) {
    /* Remove from txn, if tracked.
     * A read-only txn (!C_UNTRACK) may have been freed already,
     * so do not peek inside it.  Only write txns track cursors.
     */
    if ((mc->mc_flags & C_UNTRACK) && mc->mc_txn->mt_cursors) {
      MDB_cursor** prev = &mc->mc_txn->mt_cursors[mc->mc_dbi];
      while (*prev && *prev != mc)
        prev = &(*prev)->mc_next;
      if (*prev == mc)
        *prev = mc->mc_next;
    }
    free(mc);
  }
}

MDB_txn* mdb_cursor_txn(MDB_cursor* mc) {
  if (!mc)
    return NULL;
  return mc->mc_txn;
}

MDB_dbi mdb_cursor_dbi(MDB_cursor* mc) {
  return mc->mc_dbi;
}

/** Replace the key for a branch node with a new key.
 * Set #MDB_TXN_ERROR on failure.
 * @param[in] mc Cursor pointing to the node to operate on.
 * @param[in] key The new key to use.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_update_key(MDB_cursor* mc, MDB_val* key) {
  MDB_page* mp;
  MDB_node* node;
  char* base;
  size_t len;
  int delta, ksize, oksize;
  indx_t ptr, i, numkeys, indx;
  DKBUF;

  indx = mc->mc_ki[mc->mc_top];
  mp = mc->mc_pg[mc->mc_top];
  node = NODEPTR(mp, indx);
  ptr = mp->mp_ptrs[indx];
#if MDB_DEBUG
  {
    MDB_val k2;
    char kbuf2[DKBUF_MAXKEYSIZE * 2 + 1];
    k2.mv_data = NODEKEY(node);
    k2.mv_size = node->mn_ksize;
    DPRINTF(
        ("update key %u (ofs %u) [%s] to [%s] on page %" Yu,
         indx,
         ptr,
         mdb_dkey(&k2, kbuf2),
         DKEY(key),
         mp->mp_pgno));
  }
#endif

  /* Sizes must be 2-byte aligned. */
  ksize = EVEN(key->mv_size);
  oksize = EVEN(node->mn_ksize);
  delta = ksize - oksize;

  /* Shift node contents if EVEN(key length) changed. */
  if (delta) {
    if (delta > 0 && SIZELEFT(mp) < delta) {
      pgno_t pgno;
      /* not enough space left, do a delete and split */
      DPRINTF(("Not enough room, delta = %d, splitting...", delta));
      pgno = NODEPGNO(node);
      mdb_node_del(mc, 0);
      return mdb_page_split(mc, key, NULL, pgno, MDB_SPLIT_REPLACE);
    }

    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 + PAGEBASE;
    len = ptr - mp->mp_upper + NODESIZE;
    memmove(base - delta, base, len);
    mp->mp_upper -= delta;

    node = NODEPTR(mp, indx);
  }

  /* But even if no shift was needed, update ksize */
  if (node->mn_ksize != key->mv_size)
    node->mn_ksize = key->mv_size;

  if (key->mv_size)
    memcpy(NODEKEY(node), key->mv_data, key->mv_size);

  return MDB_SUCCESS;
}

static void mdb_cursor_copy(const MDB_cursor* csrc, MDB_cursor* cdst);

/** Perform \b act while tracking temporary cursor \b mn */
#define WITH_CURSOR_TRACKING(mn, act)                                       \
  do {                                                                      \
    MDB_cursor dummy, *tracked, **tp = &(mn).mc_txn->mt_cursors[mn.mc_dbi]; \
    if ((mn).mc_flags & C_SUB) {                                            \
      dummy.mc_flags = C_INITIALIZED;                                       \
      dummy.mc_xcursor = (MDB_xcursor*)&(mn);                               \
      tracked = &dummy;                                                     \
    } else {                                                                \
      tracked = &(mn);                                                      \
    }                                                                       \
    tracked->mc_next = *tp;                                                 \
    *tp = tracked;                                                          \
    {                                                                       \
      act;                                                                  \
    }                                                                       \
    *tp = tracked->mc_next;                                                 \
  } while (0)

/** Move a node from csrc to cdst.
 */
static int mdb_node_move(MDB_cursor* csrc, MDB_cursor* cdst, int fromleft) {
  MDB_node* srcnode;
  MDB_val key, data;
  pgno_t srcpg;
  MDB_cursor mn;
  int rc;
  unsigned short flags;

  DKBUF;

  /* Mark src and dst as dirty. */
  if ((rc = mdb_page_touch(csrc)) || (rc = mdb_page_touch(cdst)))
    return rc;

  if (IS_LEAF2(csrc->mc_pg[csrc->mc_top])) {
    key.mv_size = csrc->mc_db->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;
    srcpg = 0;
    flags = 0;
  } else {
    srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], csrc->mc_ki[csrc->mc_top]);
    mdb_cassert(csrc, !((size_t)srcnode & 1));
    srcpg = NODEPGNO(srcnode);
    flags = srcnode->mn_flags;
    if (csrc->mc_ki[csrc->mc_top] == 0 &&
        IS_BRANCH(csrc->mc_pg[csrc->mc_top])) {
      unsigned int snum = csrc->mc_snum;
      MDB_node* s2;
      /* must find the lowest key below src */
      rc = mdb_page_search_lowest(csrc);
      if (rc)
        return rc;
      if (IS_LEAF2(csrc->mc_pg[csrc->mc_top])) {
        key.mv_size = csrc->mc_db->md_pad;
        key.mv_data = LEAF2KEY(csrc->mc_pg[csrc->mc_top], 0, key.mv_size);
      } else {
        s2 = NODEPTR(csrc->mc_pg[csrc->mc_top], 0);
        key.mv_size = NODEKSZ(s2);
        key.mv_data = NODEKEY(s2);
      }
      csrc->mc_snum = snum--;
      csrc->mc_top = snum;
    } else {
      key.mv_size = NODEKSZ(srcnode);
      key.mv_data = NODEKEY(srcnode);
    }
    data.mv_size = NODEDSZ(srcnode);
    data.mv_data = NODEDATA(srcnode);
  }
  mn.mc_xcursor = NULL;
  if (IS_BRANCH(cdst->mc_pg[cdst->mc_top]) && cdst->mc_ki[cdst->mc_top] == 0) {
    unsigned int snum = cdst->mc_snum;
    MDB_node* s2;
    MDB_val bkey;
    /* must find the lowest key below dst */
    mdb_cursor_copy(cdst, &mn);
    rc = mdb_page_search_lowest(&mn);
    if (rc)
      return rc;
    if (IS_LEAF2(mn.mc_pg[mn.mc_top])) {
      bkey.mv_size = mn.mc_db->md_pad;
      bkey.mv_data = LEAF2KEY(mn.mc_pg[mn.mc_top], 0, bkey.mv_size);
    } else {
      s2 = NODEPTR(mn.mc_pg[mn.mc_top], 0);
      bkey.mv_size = NODEKSZ(s2);
      bkey.mv_data = NODEKEY(s2);
    }
    mn.mc_snum = snum--;
    mn.mc_top = snum;
    mn.mc_ki[snum] = 0;
    rc = mdb_update_key(&mn, &bkey);
    if (rc)
      return rc;
  }

  DPRINTF(
      ("moving %s node %u [%s] on page %" Yu " to node %u on page %" Yu,
       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_node_add(cdst, cdst->mc_ki[cdst->mc_top], &key, &data, srcpg, flags);
  if (rc != MDB_SUCCESS)
    return rc;

  /* Delete the node from the source page.
   */
  mdb_node_del(csrc, key.mv_size);

  {
    /* Adjust other cursors pointing to mp */
    MDB_cursor *m2, *m3;
    MDB_dbi dbi = csrc->mc_dbi;
    MDB_page *mpd, *mps;

    mps = csrc->mc_pg[csrc->mc_top];
    /* If we're adding on the left, bump others up */
    if (fromleft) {
      mpd = cdst->mc_pg[csrc->mc_top];
      for (m2 = csrc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
        if (csrc->mc_flags & C_SUB)
          m3 = &m2->mc_xcursor->mx_cursor;
        else
          m3 = m2;
        if (!(m3->mc_flags & C_INITIALIZED) || m3->mc_top < csrc->mc_top)
          continue;
        if (m3 != cdst && m3->mc_pg[csrc->mc_top] == mpd &&
            m3->mc_ki[csrc->mc_top] >= cdst->mc_ki[csrc->mc_top]) {
          m3->mc_ki[csrc->mc_top]++;
        }
        if (m3 != csrc && m3->mc_pg[csrc->mc_top] == mps &&
            m3->mc_ki[csrc->mc_top] == csrc->mc_ki[csrc->mc_top]) {
          m3->mc_pg[csrc->mc_top] = cdst->mc_pg[cdst->mc_top];
          m3->mc_ki[csrc->mc_top] = cdst->mc_ki[cdst->mc_top];
          m3->mc_ki[csrc->mc_top - 1]++;
        }
        if (IS_LEAF(mps))
          XCURSOR_REFRESH(m3, csrc->mc_top, m3->mc_pg[csrc->mc_top]);
      }
    } else
    /* Adding on the right, bump others down */
    {
      for (m2 = csrc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
        if (csrc->mc_flags & C_SUB)
          m3 = &m2->mc_xcursor->mx_cursor;
        else
          m3 = m2;
        if (m3 == csrc)
          continue;
        if (!(m3->mc_flags & C_INITIALIZED) || m3->mc_top < csrc->mc_top)
          continue;
        if (m3->mc_pg[csrc->mc_top] == mps) {
          if (!m3->mc_ki[csrc->mc_top]) {
            m3->mc_pg[csrc->mc_top] = cdst->mc_pg[cdst->mc_top];
            m3->mc_ki[csrc->mc_top] = cdst->mc_ki[cdst->mc_top];
            m3->mc_ki[csrc->mc_top - 1]--;
          } else {
            m3->mc_ki[csrc->mc_top]--;
          }
          if (IS_LEAF(mps))
            XCURSOR_REFRESH(m3, csrc->mc_top, m3->mc_pg[csrc->mc_top]);
        }
      }
    }
  }

  /* 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], 0, key.mv_size);
      } else {
        srcnode = NODEPTR(csrc->mc_pg[csrc->mc_top], 0);
        key.mv_size = NODEKSZ(srcnode);
        key.mv_data = NODEKEY(srcnode);
      }
      DPRINTF(
          ("update separator for source page %" Yu " to [%s]",
           csrc->mc_pg[csrc->mc_top]->mp_pgno,
           DKEY(&key)));
      mdb_cursor_copy(csrc, &mn);
      mn.mc_snum--;
      mn.mc_top--;
      /* We want mdb_rebalance to find mn when doing fixups */
      WITH_CURSOR_TRACKING(mn, rc = mdb_update_key(&mn, &key));
      if (rc)
        return rc;
    }
    if (IS_BRANCH(csrc->mc_pg[csrc->mc_top])) {
      MDB_val nullkey;
      indx_t ix = csrc->mc_ki[csrc->mc_top];
      nullkey.mv_size = 0;
      csrc->mc_ki[csrc->mc_top] = 0;
      rc = mdb_update_key(csrc, &nullkey);
      csrc->mc_ki[csrc->mc_top] = ix;
      mdb_cassert(csrc, rc == 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 %" Yu " to [%s]",
           cdst->mc_pg[cdst->mc_top]->mp_pgno,
           DKEY(&key)));
      mdb_cursor_copy(cdst, &mn);
      mn.mc_snum--;
      mn.mc_top--;
      /* We want mdb_rebalance to find mn when doing fixups */
      WITH_CURSOR_TRACKING(mn, rc = mdb_update_key(&mn, &key));
      if (rc)
        return rc;
    }
    if (IS_BRANCH(cdst->mc_pg[cdst->mc_top])) {
      MDB_val nullkey;
      indx_t ix = cdst->mc_ki[cdst->mc_top];
      nullkey.mv_size = 0;
      cdst->mc_ki[cdst->mc_top] = 0;
      rc = mdb_update_key(cdst, &nullkey);
      cdst->mc_ki[cdst->mc_top] = ix;
      mdb_cassert(cdst, rc == MDB_SUCCESS);
    }
  }

  return MDB_SUCCESS;
}

/** Merge one page into another.
 *  The nodes from the page pointed to by \b csrc will
 *	be copied to the page pointed to by \b cdst and then
 *	the \b csrc page will be freed.
 * @param[in] csrc Cursor pointing to the source page.
 * @param[in] cdst Cursor pointing to the destination page.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_merge(MDB_cursor* csrc, MDB_cursor* cdst) {
  MDB_page *psrc, *pdst;
  MDB_node* srcnode;
  MDB_val key, data;
  unsigned nkeys;
  int rc;
  indx_t i, j;

  psrc = csrc->mc_pg[csrc->mc_top];
  pdst = cdst->mc_pg[cdst->mc_top];

  DPRINTF(("merging page %" Yu " into %" Yu, psrc->mp_pgno, pdst->mp_pgno));

  mdb_cassert(csrc, csrc->mc_snum > 1); /* can't merge root page */
  mdb_cassert(csrc, cdst->mc_snum > 1);

  /* Mark dst as dirty. */
  if ((rc = mdb_page_touch(cdst)))
    return rc;

  /* get dst page again now that we've touched it. */
  pdst = cdst->mc_pg[cdst->mc_top];

  /* Move all nodes from src to dst.
   */
  j = nkeys = NUMKEYS(pdst);
  if (IS_LEAF2(psrc)) {
    key.mv_size = csrc->mc_db->md_pad;
    key.mv_data = METADATA(psrc);
    for (i = 0; i < NUMKEYS(psrc); i++, j++) {
      rc = mdb_node_add(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(psrc); i++, j++) {
      srcnode = NODEPTR(psrc, i);
      if (i == 0 && IS_BRANCH(psrc)) {
        MDB_cursor mn;
        MDB_node* s2;
        mdb_cursor_copy(csrc, &mn);
        mn.mc_xcursor = NULL;
        /* must find the lowest key below src */
        rc = mdb_page_search_lowest(&mn);
        if (rc)
          return rc;
        if (IS_LEAF2(mn.mc_pg[mn.mc_top])) {
          key.mv_size = mn.mc_db->md_pad;
          key.mv_data = LEAF2KEY(mn.mc_pg[mn.mc_top], 0, key.mv_size);
        } else {
          s2 = NODEPTR(mn.mc_pg[mn.mc_top], 0);
          key.mv_size = NODEKSZ(s2);
          key.mv_data = NODEKEY(s2);
        }
      } else {
        key.mv_size = srcnode->mn_ksize;
        key.mv_data = NODEKEY(srcnode);
      }

      data.mv_size = NODEDSZ(srcnode);
      data.mv_data = NODEDATA(srcnode);
      rc = mdb_node_add(
          cdst, j, &key, &data, NODEPGNO(srcnode), srcnode->mn_flags);
      if (rc != MDB_SUCCESS)
        return rc;
    }
  }

  DPRINTF(
      ("dst page %" Yu " now has %u keys (%.1f%% filled)",
       pdst->mp_pgno,
       NUMKEYS(pdst),
       (float)PAGEFILL(cdst->mc_txn->mt_env, pdst) / 10));

  /* Unlink the src page from parent and add to free list.
   */
  csrc->mc_top--;
  mdb_node_del(csrc, 0);
  if (csrc->mc_ki[csrc->mc_top] == 0) {
    key.mv_size = 0;
    rc = mdb_update_key(csrc, &key);
    if (rc) {
      csrc->mc_top++;
      return rc;
    }
  }
  csrc->mc_top++;

  psrc = csrc->mc_pg[csrc->mc_top];
  /* If not operating on FreeDB, allow this page to be reused
   * in this txn. Otherwise just add to free list.
   */
  rc = mdb_page_loose(csrc, psrc);
  if (rc)
    return rc;
  if (IS_LEAF(psrc))
    csrc->mc_db->md_leaf_pages--;
  else
    csrc->mc_db->md_branch_pages--;
  {
    /* Adjust other cursors pointing to mp */
    MDB_cursor *m2, *m3;
    MDB_dbi dbi = csrc->mc_dbi;
    unsigned int top = csrc->mc_top;

    for (m2 = csrc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
      if (csrc->mc_flags & C_SUB)
        m3 = &m2->mc_xcursor->mx_cursor;
      else
        m3 = m2;
      if (m3 == csrc)
        continue;
      if (m3->mc_snum < csrc->mc_snum)
        continue;
      if (m3->mc_pg[top] == psrc) {
        m3->mc_pg[top] = pdst;
        m3->mc_ki[top] += nkeys;
        m3->mc_ki[top - 1] = cdst->mc_ki[top - 1];
      } else if (
          m3->mc_pg[top - 1] == csrc->mc_pg[top - 1] &&
          m3->mc_ki[top - 1] > csrc->mc_ki[top - 1]) {
        m3->mc_ki[top - 1]--;
      }
      if (IS_LEAF(psrc))
        XCURSOR_REFRESH(m3, top, m3->mc_pg[top]);
    }
  }
  {
    unsigned int snum = cdst->mc_snum;
    uint16_t depth = cdst->mc_db->md_depth;
    mdb_cursor_pop(cdst);
    rc = mdb_rebalance(cdst);
    /* Did the tree height change? */
    if (depth != cdst->mc_db->md_depth)
      snum += cdst->mc_db->md_depth - depth;
    cdst->mc_snum = snum;
    cdst->mc_top = snum - 1;
  }
  return rc;
}

/** Copy the contents of a cursor.
 * @param[in] csrc The cursor to copy from.
 * @param[out] cdst The cursor to copy to.
 */
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_db = csrc->mc_db;
  cdst->mc_dbx = csrc->mc_dbx;
  cdst->mc_snum = csrc->mc_snum;
  cdst->mc_top = csrc->mc_top;
  cdst->mc_flags = csrc->mc_flags;
  MC_SET_OVPG(cdst, MC_OVPG(csrc));

  for (i = 0; i < csrc->mc_snum; i++) {
    cdst->mc_pg[i] = csrc->mc_pg[i];
    cdst->mc_ki[i] = csrc->mc_ki[i];
  }
}

/** Rebalance the tree after a delete operation.
 * @param[in] mc Cursor pointing to the page where rebalancing
 * should begin.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_rebalance(MDB_cursor* mc) {
  MDB_node* node;
  int rc, fromleft;
  unsigned int ptop, minkeys, thresh;
  MDB_cursor mn;
  indx_t oldki;

  if (IS_BRANCH(mc->mc_pg[mc->mc_top])) {
    minkeys = 2;
    thresh = 1;
  } else {
    minkeys = 1;
    thresh = FILL_THRESHOLD;
  }
  DPRINTF(
      ("rebalancing %s page %" Yu " (has %u keys, %.1f%% full)",
       IS_LEAF(mc->mc_pg[mc->mc_top]) ? "leaf" : "branch",
       mdb_dbg_pgno(mc->mc_pg[mc->mc_top]),
       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]) >= thresh &&
      NUMKEYS(mc->mc_pg[mc->mc_top]) >= minkeys) {
    DPRINTF(
        ("no need to rebalance page %" Yu ", above fill threshold",
         mdb_dbg_pgno(mc->mc_pg[mc->mc_top])));
    return MDB_SUCCESS;
  }

  if (mc->mc_snum < 2) {
    MDB_page* mp = mc->mc_pg[0];
    if (IS_SUBP(mp)) {
      DPUTS("Can't rebalance a subpage, ignoring");
      return MDB_SUCCESS;
    }
    if (NUMKEYS(mp) == 0) {
      DPUTS("tree is completely empty");
      mc->mc_db->md_root = P_INVALID;
      mc->mc_db->md_depth = 0;
      mc->mc_db->md_leaf_pages = 0;
      rc = mdb_midl_append(&mc->mc_txn->mt_free_pgs, mp->mp_pgno);
      if (rc)
        return rc;
      /* Adjust cursors pointing to mp */
      mc->mc_snum = 0;
      mc->mc_top = 0;
      mc->mc_flags &= ~C_INITIALIZED;
      {
        MDB_cursor *m2, *m3;
        MDB_dbi dbi = mc->mc_dbi;

        for (m2 = mc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
          if (mc->mc_flags & C_SUB)
            m3 = &m2->mc_xcursor->mx_cursor;
          else
            m3 = m2;
          if (!(m3->mc_flags & C_INITIALIZED) || (m3->mc_snum < mc->mc_snum))
            continue;
          if (m3->mc_pg[0] == mp) {
            m3->mc_snum = 0;
            m3->mc_top = 0;
            m3->mc_flags &= ~C_INITIALIZED;
          }
        }
      }
    } else if (IS_BRANCH(mp) && NUMKEYS(mp) == 1) {
      int i;
      DPUTS("collapsing root page!");
      rc = mdb_midl_append(&mc->mc_txn->mt_free_pgs, mp->mp_pgno);
      if (rc)
        return rc;
      mc->mc_db->md_root = NODEPGNO(NODEPTR(mp, 0));
      rc = mdb_page_get(mc, mc->mc_db->md_root, &mc->mc_pg[0], NULL);
      if (rc)
        return rc;
      mc->mc_db->md_depth--;
      mc->mc_db->md_branch_pages--;
      mc->mc_ki[0] = mc->mc_ki[1];
      for (i = 1; i < mc->mc_db->md_depth; i++) {
        mc->mc_pg[i] = mc->mc_pg[i + 1];
        mc->mc_ki[i] = mc->mc_ki[i + 1];
      }
      {
        /* Adjust other cursors pointing to mp */
        MDB_cursor *m2, *m3;
        MDB_dbi dbi = mc->mc_dbi;

        for (m2 = mc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
          if (mc->mc_flags & C_SUB)
            m3 = &m2->mc_xcursor->mx_cursor;
          else
            m3 = m2;
          if (m3 == mc)
            continue;
          if (!(m3->mc_flags & C_INITIALIZED))
            continue;
          if (m3->mc_pg[0] == mp) {
            for (i = 0; i < mc->mc_db->md_depth; i++) {
              m3->mc_pg[i] = m3->mc_pg[i + 1];
              m3->mc_ki[i] = m3->mc_ki[i + 1];
            }
            m3->mc_snum--;
            m3->mc_top--;
          }
        }
      }
    } 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;
  mdb_cassert(mc, 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;

  oldki = mc->mc_ki[mc->mc_top];
  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]);
    rc = mdb_page_get(mc, NODEPGNO(node), &mn.mc_pg[mn.mc_top], NULL);
    if (rc)
      return rc;
    mn.mc_ki[mn.mc_top] = 0;
    mc->mc_ki[mc->mc_top] = NUMKEYS(mc->mc_pg[mc->mc_top]);
    fromleft = 0;
  } 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]);
    rc = mdb_page_get(mc, NODEPGNO(node), &mn.mc_pg[mn.mc_top], NULL);
    if (rc)
      return rc;
    mn.mc_ki[mn.mc_top] = NUMKEYS(mn.mc_pg[mn.mc_top]) - 1;
    mc->mc_ki[mc->mc_top] = 0;
    fromleft = 1;
  }

  DPRINTF(
      ("found neighbor page %" Yu " (%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 enough keys,
   * move one key from it. Otherwise we should try to merge them.
   * (A branch page must never have less than 2 keys.)
   */
  if (PAGEFILL(mc->mc_txn->mt_env, mn.mc_pg[mn.mc_top]) >= thresh &&
      NUMKEYS(mn.mc_pg[mn.mc_top]) > minkeys) {
    rc = mdb_node_move(&mn, mc, fromleft);
    if (fromleft) {
      /* if we inserted on left, bump position up */
      oldki++;
    }
  } else {
    if (!fromleft) {
      rc = mdb_page_merge(&mn, mc);
    } else {
      oldki += NUMKEYS(mn.mc_pg[mn.mc_top]);
      mn.mc_ki[mn.mc_top] += mc->mc_ki[mn.mc_top] + 1;
      /* We want mdb_rebalance to find mn when doing fixups */
      WITH_CURSOR_TRACKING(mn, rc = mdb_page_merge(mc, &mn));
      mdb_cursor_copy(&mn, mc);
    }
    mc->mc_flags &= ~C_EOF;
  }
  mc->mc_ki[mc->mc_top] = oldki;
  return rc;
}

/** Complete a delete operation started by #mdb_cursor_del(). */
static int mdb_cursor_del0(MDB_cursor* mc) {
  int rc;
  MDB_page* mp;
  indx_t ki;
  unsigned int nkeys;
  MDB_cursor *m2, *m3;
  MDB_dbi dbi = mc->mc_dbi;

  ki = mc->mc_ki[mc->mc_top];
  mp = mc->mc_pg[mc->mc_top];
  mdb_node_del(mc, mc->mc_db->md_pad);
  mc->mc_db->md_entries--;
  {
    /* Adjust other cursors pointing to mp */
    for (m2 = mc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
      m3 = (mc->mc_flags & C_SUB) ? &m2->mc_xcursor->mx_cursor : m2;
      if (!(m2->mc_flags & m3->mc_flags & C_INITIALIZED))
        continue;
      if (m3 == mc || m3->mc_snum < mc->mc_snum)
        continue;
      if (m3->mc_pg[mc->mc_top] == mp) {
        if (m3->mc_ki[mc->mc_top] == ki) {
          m3->mc_flags |= C_DEL;
          if (mc->mc_db->md_flags & MDB_DUPSORT) {
            /* Sub-cursor referred into dataset which is gone */
            m3->mc_xcursor->mx_cursor.mc_flags &= ~(C_INITIALIZED | C_EOF);
          }
          continue;
        } else if (m3->mc_ki[mc->mc_top] > ki) {
          m3->mc_ki[mc->mc_top]--;
        }
        XCURSOR_REFRESH(m3, mc->mc_top, mp);
      }
    }
  }
  rc = mdb_rebalance(mc);
  if (rc)
    goto fail;

  /* DB is totally empty now, just bail out.
   * Other cursors adjustments were already done
   * by mdb_rebalance and aren't needed here.
   */
  if (!mc->mc_snum) {
    mc->mc_flags |= C_EOF;
    return rc;
  }

  mp = mc->mc_pg[mc->mc_top];
  nkeys = NUMKEYS(mp);

  /* Adjust other cursors pointing to mp */
  for (m2 = mc->mc_txn->mt_cursors[dbi]; !rc && m2; m2 = m2->mc_next) {
    m3 = (mc->mc_flags & C_SUB) ? &m2->mc_xcursor->mx_cursor : m2;
    if (!(m2->mc_flags & m3->mc_flags & C_INITIALIZED))
      continue;
    if (m3->mc_snum < mc->mc_snum)
      continue;
    if (m3->mc_pg[mc->mc_top] == mp) {
      if (m3->mc_ki[mc->mc_top] >= mc->mc_ki[mc->mc_top]) {
        /* if m3 points past last node in page, find next sibling */
        if (m3->mc_ki[mc->mc_top] >= nkeys) {
          rc = mdb_cursor_sibling(m3, 1);
          if (rc == MDB_NOTFOUND) {
            m3->mc_flags |= C_EOF;
            rc = MDB_SUCCESS;
            continue;
          }
          if (rc)
            goto fail;
        }
        if (m3->mc_xcursor && !(m3->mc_flags & C_EOF)) {
          MDB_node* node =
              NODEPTR(m3->mc_pg[mc->mc_top], m3->mc_ki[mc->mc_top]);
          /* If this node has dupdata, it may need to be reinited
           * because its data has moved.
           * If the xcursor was not initd it must be reinited.
           * Else if node points to a subDB, nothing is needed.
           * Else (xcursor was initd, not a subDB) needs mc_pg[0] reset.
           */
          if (node->mn_flags & F_DUPDATA) {
            if (m3->mc_xcursor->mx_cursor.mc_flags & C_INITIALIZED) {
              if (!(node->mn_flags & F_SUBDATA))
                m3->mc_xcursor->mx_cursor.mc_pg[0] = NODEDATA(node);
            } else {
              mdb_xcursor_init1(m3, node);
              rc = mdb_cursor_first(&m3->mc_xcursor->mx_cursor, NULL, NULL);
              if (rc)
                goto fail;
            }
          }
          m3->mc_xcursor->mx_cursor.mc_flags |= C_DEL;
        }
      }
    }
  }
  mc->mc_flags |= C_DEL;

fail:
  if (rc)
    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) {
  DKBUF;
  DDBUF;
  if (!key || !TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;

  if (txn->mt_flags & (MDB_TXN_RDONLY | MDB_TXN_BLOCKED))
    return (txn->mt_flags & MDB_TXN_RDONLY) ? EACCES : MDB_BAD_TXN;

  if (!F_ISSET(txn->mt_dbs[dbi].md_flags, MDB_DUPSORT)) {
    /* must ignore any data */
    data = NULL;
  }

  MDB_TRACE(
      ("%p, %u, %" Z "u[%s], %" Z "u%s",
       txn,
       dbi,
       key ? key->mv_size : 0,
       DKEY(key),
       data ? data->mv_size : 0,
       data ? mdb_dval(txn, dbi, data, dbuf) : ""));
  return mdb_del0(txn, dbi, key, data, 0);
}

static int mdb_del0(
    MDB_txn* txn,
    MDB_dbi dbi,
    MDB_val* key,
    MDB_val* data,
    unsigned flags) {
  MDB_cursor mc;
  MDB_xcursor mx;
  MDB_cursor_op op;
  MDB_val rdata, *xdata;
  int rc, exact = 0;
  DKBUF;

  DPRINTF(("====> delete db %u key [%s]", dbi, DKEY(key)));

  mdb_cursor_init(&mc, txn, dbi, &mx);

  if (data) {
    op = MDB_GET_BOTH;
    rdata = *data;
    xdata = &rdata;
  } else {
    op = MDB_SET;
    xdata = NULL;
    flags |= MDB_NODUPDATA;
  }
  rc = mdb_cursor_set(&mc, key, xdata, op, &exact);
  if (rc == 0) {
    /* let mdb_page_split know about this cursor if needed:
     * delete will trigger a rebalance; if it needs to move
     * a node from one page to another, it will have to
     * update the parent's separator key(s). If the new sepkey
     * is larger than the current one, the parent page may
     * run out of space, triggering a split. We need this
     * cursor to be consistent until the end of the rebalance.
     */
    mc.mc_next = txn->mt_cursors[dbi];
    txn->mt_cursors[dbi] = &mc;
    rc = _mdb_cursor_del(&mc, flags);
    txn->mt_cursors[dbi] = mc.mc_next;
  }
  return rc;
}

/** Split a page and insert a new node.
 * Set #MDB_TXN_ERROR on failure.
 * @param[in,out] mc Cursor pointing to the page and desired insertion index.
 * The cursor will be updated to point to the actual page and index where
 * the node got inserted after the split.
 * @param[in] newkey The key for the newly inserted node.
 * @param[in] newdata The data for the newly inserted node.
 * @param[in] newpgno The page number, if the new node is a branch node.
 * @param[in] nflags The #NODE_ADD_FLAGS for the new node.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_page_split(
    MDB_cursor* mc,
    MDB_val* newkey,
    MDB_val* newdata,
    pgno_t newpgno,
    unsigned int nflags) {
  unsigned int flags;
  int rc = MDB_SUCCESS, new_root = 0, did_split = 0;
  indx_t newindx;
  pgno_t pgno = 0;
  int i, j, split_indx, nkeys, pmax;
  MDB_env* env = mc->mc_txn->mt_env;
  MDB_node* node;
  MDB_val sepkey, rkey, xdata, *rdata = &xdata;
  MDB_page* copy = NULL;
  MDB_page *mp, *rp, *pp;
  int ptop;
  MDB_cursor mn;
  DKBUF;

  mp = mc->mc_pg[mc->mc_top];
  newindx = mc->mc_ki[mc->mc_top];
  nkeys = NUMKEYS(mp);

  DPRINTF(
      ("-----> splitting %s page %" Yu " and adding [%s] at index %i/%i",
       IS_LEAF(mp) ? "leaf" : "branch",
       mp->mp_pgno,
       DKEY(newkey),
       mc->mc_ki[mc->mc_top],
       nkeys));

  /* Create a right sibling. */
  if ((rc = mdb_page_new(mc, mp->mp_flags, 1, &rp)))
    return rc;
  rp->mp_pad = mp->mp_pad;
  DPRINTF(("new right sibling: page %" Yu, rp->mp_pgno));

  /* Usually when splitting the root page, the cursor
   * height is 1. But when called from mdb_update_key,
   * the cursor height may be greater because it walks
   * up the stack while finding the branch slot to update.
   */
  if (mc->mc_top < 1) {
    if ((rc = mdb_page_new(mc, P_BRANCH, 1, &pp)))
      goto done;
    /* shift current top to make room for new parent */
    for (i = mc->mc_snum; i > 0; i--) {
      mc->mc_pg[i] = mc->mc_pg[i - 1];
      mc->mc_ki[i] = mc->mc_ki[i - 1];
    }
    mc->mc_pg[0] = pp;
    mc->mc_ki[0] = 0;
    mc->mc_db->md_root = pp->mp_pgno;
    DPRINTF(("root split! new root = %" Yu, pp->mp_pgno));
    new_root = mc->mc_db->md_depth++;

    /* Add left (implicit) pointer. */
    if ((rc = mdb_node_add(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_db->md_root = mp->mp_pgno;
      mc->mc_db->md_depth--;
      goto done;
    }
    mc->mc_snum++;
    mc->mc_top++;
    ptop = 0;
  } else {
    ptop = mc->mc_top - 1;
    DPRINTF(("parent branch page is %" Yu, mc->mc_pg[ptop]->mp_pgno));
  }

  mdb_cursor_copy(mc, &mn);
  mn.mc_xcursor = NULL;
  mn.mc_pg[mn.mc_top] = rp;
  mn.mc_ki[ptop] = mc->mc_ki[ptop] + 1;

  if (nflags & MDB_APPEND) {
    mn.mc_ki[mn.mc_top] = 0;
    sepkey = *newkey;
    split_indx = newindx;
    nkeys = 0;
  } else {
    split_indx = (nkeys + 1) / 2;

    if (IS_LEAF2(rp)) {
      char *split, *ins;
      int x;
      unsigned int lsize, rsize, ksize;
      /* Move half of the keys to the right sibling */
      x = mc->mc_ki[mc->mc_top] - split_indx;
      ksize = mc->mc_db->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;
      }
    } else {
      int psize, nsize, k, keythresh;

      /* Maximum free space in an empty page */
      pmax = env->me_psize - PAGEHDRSZ;
      /* Threshold number of keys considered "small" */
      keythresh = env->me_psize >> 7;

      if (IS_LEAF(mp))
        nsize = mdb_leaf_size(env, newkey, newdata);
      else
        nsize = mdb_branch_size(env, newkey);
      nsize = EVEN(nsize);

      /* grab a page to hold a temporary copy */
      copy = mdb_page_malloc(mc->mc_txn, 1);
      if (copy == NULL) {
        rc = ENOMEM;
        goto done;
      }
      copy->mp_pgno = mp->mp_pgno;
      copy->mp_flags = mp->mp_flags;
      copy->mp_lower = (PAGEHDRSZ - PAGEBASE);
      copy->mp_upper = env->me_psize - PAGEBASE;

      /* prepare to insert */
      for (i = 0, j = 0; i < nkeys; i++) {
        if (i == newindx) {
          copy->mp_ptrs[j++] = 0;
        }
        copy->mp_ptrs[j++] = mp->mp_ptrs[i];
      }

      /* When items are relatively large the split point needs
       * to be checked, because being off-by-one will make the
       * difference between success or failure in mdb_node_add.
       *
       * It's also relevant if a page happens to be laid out
       * such that one half of its nodes are all "small" and
       * the other half of its nodes are "large." If the new
       * item is also "large" and falls on the half with
       * "large" nodes, it also may not fit.
       *
       * As a final tweak, if the new item goes on the last
       * spot on the page (and thus, onto the new page), bias
       * the split so the new page is emptier than the old page.
       * This yields better packing during sequential inserts.
       */
      if (nkeys < keythresh || nsize > pmax / 16 || newindx >= nkeys) {
        /* Find split point */
        psize = 0;
        if (newindx <= split_indx || newindx >= nkeys) {
          i = 0;
          j = 1;
          k = newindx >= nkeys ? nkeys : split_indx + 1 + IS_LEAF(mp);
        } else {
          i = nkeys;
          j = -1;
          k = split_indx - 1;
        }
        for (; i != k; i += j) {
          if (i == newindx) {
            psize += nsize;
            node = NULL;
          } else {
            node = (MDB_node*)((char*)mp + copy->mp_ptrs[i] + PAGEBASE);
            psize += NODESIZE + NODEKSZ(node) + sizeof(indx_t);
            if (IS_LEAF(mp)) {
              if (F_ISSET(node->mn_flags, F_BIGDATA))
                psize += sizeof(pgno_t);
              else
                psize += NODEDSZ(node);
            }
            psize = EVEN(psize);
          }
          if (psize > pmax || i == k - j) {
            split_indx = i + (j < 0);
            break;
          }
        }
      }
      if (split_indx == newindx) {
        sepkey.mv_size = newkey->mv_size;
        sepkey.mv_data = newkey->mv_data;
      } else {
        node = (MDB_node*)((char*)mp + copy->mp_ptrs[split_indx] + PAGEBASE);
        sepkey.mv_size = node->mn_ksize;
        sepkey.mv_data = NODEKEY(node);
      }
    }
  }

  DPRINTF(("separator is %d [%s]", split_indx, DKEY(&sepkey)));

  /* Copy separator key to the parent.
   */
  if (SIZELEFT(mn.mc_pg[ptop]) < mdb_branch_size(env, &sepkey)) {
    int snum = mc->mc_snum;
    mn.mc_snum--;
    mn.mc_top--;
    did_split = 1;
    /* We want other splits to find mn when doing fixups */
    WITH_CURSOR_TRACKING(
        mn, rc = mdb_page_split(&mn, &sepkey, NULL, rp->mp_pgno, 0));
    if (rc)
      goto done;

    /* root split? */
    if (mc->mc_snum > snum) {
      ptop++;
    }
    /* 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])) {
      for (i = 0; i < ptop; i++) {
        mc->mc_pg[i] = mn.mc_pg[i];
        mc->mc_ki[i] = mn.mc_ki[i];
      }
      mc->mc_pg[ptop] = mn.mc_pg[ptop];
      if (mn.mc_ki[ptop]) {
        mc->mc_ki[ptop] = mn.mc_ki[ptop] - 1;
      } else {
        /* find right page's left sibling */
        mc->mc_ki[ptop] = mn.mc_ki[ptop];
        rc = mdb_cursor_sibling(mc, 0);
      }
    }
  } else {
    mn.mc_top--;
    rc = mdb_node_add(&mn, mn.mc_ki[ptop], &sepkey, NULL, rp->mp_pgno, 0);
    mn.mc_top++;
  }
  if (rc != MDB_SUCCESS) {
    if (rc == MDB_NOTFOUND) /* improper mdb_cursor_sibling() result */
      rc = MDB_PROBLEM;
    goto done;
  }
  if (nflags & MDB_APPEND) {
    mc->mc_pg[mc->mc_top] = rp;
    mc->mc_ki[mc->mc_top] = 0;
    rc = mdb_node_add(mc, 0, newkey, newdata, newpgno, nflags);
    if (rc)
      goto done;
    for (i = 0; i < mc->mc_top; i++)
      mc->mc_ki[i] = mn.mc_ki[i];
  } else if (!IS_LEAF2(mp)) {
    /* Move nodes */
    mc->mc_pg[mc->mc_top] = rp;
    i = split_indx;
    j = 0;
    do {
      if (i == newindx) {
        rkey.mv_data = newkey->mv_data;
        rkey.mv_size = newkey->mv_size;
        if (IS_LEAF(mp)) {
          rdata = newdata;
        } else
          pgno = newpgno;
        flags = nflags;
        /* Update index for the new key. */
        mc->mc_ki[mc->mc_top] = j;
      } else {
        node = (MDB_node*)((char*)mp + copy->mp_ptrs[i] + PAGEBASE);
        rkey.mv_data = NODEKEY(node);
        rkey.mv_size = node->mn_ksize;
        if (IS_LEAF(mp)) {
          xdata.mv_data = NODEDATA(node);
          xdata.mv_size = NODEDSZ(node);
          rdata = &xdata;
        } else
          pgno = NODEPGNO(node);
        flags = node->mn_flags;
      }

      if (!IS_LEAF(mp) && j == 0) {
        /* First branch index doesn't need key data. */
        rkey.mv_size = 0;
      }

      rc = mdb_node_add(mc, j, &rkey, rdata, pgno, flags);
      if (rc)
        goto done;
      if (i == nkeys) {
        i = 0;
        j = 0;
        mc->mc_pg[mc->mc_top] = copy;
      } else {
        i++;
        j++;
      }
    } while (i != split_indx);

    nkeys = NUMKEYS(copy);
    for (i = 0; i < nkeys; i++)
      mp->mp_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),
        env->me_psize - copy->mp_upper - PAGEBASE);

    /* reset back to original page */
    if (newindx < split_indx) {
      mc->mc_pg[mc->mc_top] = mp;
    } else {
      mc->mc_pg[mc->mc_top] = rp;
      mc->mc_ki[ptop]++;
      /* Make sure mc_ki is still valid.
       */
      if (mn.mc_pg[ptop] != mc->mc_pg[ptop] &&
          mc->mc_ki[ptop] >= NUMKEYS(mc->mc_pg[ptop])) {
        for (i = 0; i <= ptop; i++) {
          mc->mc_pg[i] = mn.mc_pg[i];
          mc->mc_ki[i] = mn.mc_ki[i];
        }
      }
    }
    if (nflags & MDB_RESERVE) {
      node = NODEPTR(mc->mc_pg[mc->mc_top], mc->mc_ki[mc->mc_top]);
      if (!(node->mn_flags & F_BIGDATA))
        newdata->mv_data = NODEDATA(node);
    }
  } else {
    if (newindx >= split_indx) {
      mc->mc_pg[mc->mc_top] = rp;
      mc->mc_ki[ptop]++;
      /* Make sure mc_ki is still valid.
       */
      if (mn.mc_pg[ptop] != mc->mc_pg[ptop] &&
          mc->mc_ki[ptop] >= NUMKEYS(mc->mc_pg[ptop])) {
        for (i = 0; i <= ptop; i++) {
          mc->mc_pg[i] = mn.mc_pg[i];
          mc->mc_ki[i] = mn.mc_ki[i];
        }
      }
    }
  }

  {
    /* Adjust other cursors pointing to mp */
    MDB_cursor *m2, *m3;
    MDB_dbi dbi = mc->mc_dbi;
    nkeys = NUMKEYS(mp);

    for (m2 = mc->mc_txn->mt_cursors[dbi]; m2; m2 = m2->mc_next) {
      if (mc->mc_flags & C_SUB)
        m3 = &m2->mc_xcursor->mx_cursor;
      else
        m3 = m2;
      if (m3 == mc)
        continue;
      if (!(m2->mc_flags & m3->mc_flags & C_INITIALIZED))
        continue;
      if (new_root) {
        int k;
        /* sub cursors may be on different DB */
        if (m3->mc_pg[0] != mp)
          continue;
        /* root split */
        for (k = new_root; k >= 0; k--) {
          m3->mc_ki[k + 1] = m3->mc_ki[k];
          m3->mc_pg[k + 1] = m3->mc_pg[k];
        }
        if (m3->mc_ki[0] >= nkeys) {
          m3->mc_ki[0] = 1;
        } else {
          m3->mc_ki[0] = 0;
        }
        m3->mc_pg[0] = mc->mc_pg[0];
        m3->mc_snum++;
        m3->mc_top++;
      }
      if (m3->mc_top >= mc->mc_top && m3->mc_pg[mc->mc_top] == mp) {
        if (m3->mc_ki[mc->mc_top] >= newindx && !(nflags & MDB_SPLIT_REPLACE))
          m3->mc_ki[mc->mc_top]++;
        if (m3->mc_ki[mc->mc_top] >= nkeys) {
          m3->mc_pg[mc->mc_top] = rp;
          m3->mc_ki[mc->mc_top] -= nkeys;
          for (i = 0; i < mc->mc_top; i++) {
            m3->mc_ki[i] = mn.mc_ki[i];
            m3->mc_pg[i] = mn.mc_pg[i];
          }
        }
      } else if (
          !did_split && m3->mc_top >= ptop &&
          m3->mc_pg[ptop] == mc->mc_pg[ptop] &&
          m3->mc_ki[ptop] >= mc->mc_ki[ptop]) {
        m3->mc_ki[ptop]++;
      }
      if (IS_LEAF(mp))
        XCURSOR_REFRESH(m3, mc->mc_top, m3->mc_pg[mc->mc_top]);
    }
  }
  DPRINTF(("mp left: %d, rp left: %d", SIZELEFT(mp), SIZELEFT(rp)));

done:
  if (copy) /* tmp page */
    mdb_page_free(env, copy);
  if (rc)
    mc->mc_txn->mt_flags |= MDB_TXN_ERROR;
  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;
  int rc;
  DKBUF;
  DDBUF;

  if (!key || !data || !TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;

  if (flags &
      ~(MDB_NOOVERWRITE | MDB_NODUPDATA | MDB_RESERVE | MDB_APPEND |
        MDB_APPENDDUP))
    return EINVAL;

  if (txn->mt_flags & (MDB_TXN_RDONLY | MDB_TXN_BLOCKED))
    return (txn->mt_flags & MDB_TXN_RDONLY) ? EACCES : MDB_BAD_TXN;

  MDB_TRACE(
      ("%p, %u, %" Z "u[%s], %" Z "u%s, %u",
       txn,
       dbi,
       key ? key->mv_size : 0,
       DKEY(key),
       data->mv_size,
       mdb_dval(txn, dbi, data, dbuf),
       flags));
  mdb_cursor_init(&mc, txn, dbi, &mx);
  mc.mc_next = txn->mt_cursors[dbi];
  txn->mt_cursors[dbi] = &mc;
  rc = _mdb_cursor_put(&mc, key, data, flags);
  txn->mt_cursors[dbi] = mc.mc_next;
  return rc;
}

#ifndef MDB_WBUF
#define MDB_WBUF (1024 * 1024)
#endif
#define MDB_EOF 0x10 /**< #mdb_env_copyfd1() is done reading */

/** State needed for a double-buffering compacting copy. */
typedef struct mdb_copy {
  MDB_env* mc_env;
  MDB_txn* mc_txn;
  pthread_mutex_t mc_mutex;
  pthread_cond_t mc_cond; /**< Condition variable for #mc_new */
  char* mc_wbuf[2];
  char* mc_over[2];
  size_t mc_wlen[2];
  size_t mc_olen[2];
  pgno_t mc_next_pgno;
  HANDLE mc_fd;
  int mc_toggle; /**< Buffer number in provider */
  int mc_new; /**< (0-2 buffers to write) | (#MDB_EOF at end) */
  /** Error code.  Never cleared if set.  Both threads can set nonzero
   *	to fail the copy.  Not mutex-protected, LMDB expects atomic int.
   */
  volatile int mc_error;
} mdb_copy;

/** Dedicated writer thread for compacting copy. */
static THREAD_RET ESECT CALL_CONV mdb_env_copythr(void* arg) {
  mdb_copy* my = arg;
  char* ptr;
  int toggle = 0, rc;
  size_t wsize;
#ifdef _WIN32
  DWORD len;
#define DO_WRITE(rc, fd, ptr, w2, len) rc = WriteFile(fd, ptr, w2, &len, NULL)
#else
  int len;
#define DO_WRITE(rc, fd, ptr, w2, len) \
  len = write(fd, ptr, w2);            \
  rc = (len >= 0)
#ifdef SIGPIPE
  sigset_t set;
  sigemptyset(&set);
  sigaddset(&set, SIGPIPE);
  if ((rc = pthread_sigmask(SIG_BLOCK, &set, NULL)) != 0)
    my->mc_error = rc;
#endif
#endif

  pthread_mutex_lock(&my->mc_mutex);
  for (;;) {
    while (!my->mc_new)
      pthread_cond_wait(&my->mc_cond, &my->mc_mutex);
    if (my->mc_new == 0 + MDB_EOF) /* 0 buffers, just EOF */
      break;
    wsize = my->mc_wlen[toggle];
    ptr = my->mc_wbuf[toggle];
  again:
    rc = MDB_SUCCESS;
    while (wsize > 0 && !my->mc_error) {
      DO_WRITE(rc, my->mc_fd, ptr, wsize, len);
      if (!rc) {
        rc = ErrCode();
#if defined(SIGPIPE) && !defined(_WIN32)
        if (rc == EPIPE) {
          /* Collect the pending SIGPIPE, otherwise at least OS X
           * gives it to the process on thread-exit (ITS#8504).
           */
          int tmp;
          sigwait(&set, &tmp);
        }
#endif
        break;
      } else if (len > 0) {
        rc = MDB_SUCCESS;
        ptr += len;
        wsize -= len;
        continue;
      } else {
        rc = EIO;
        break;
      }
    }
    if (rc) {
      my->mc_error = rc;
    }
    /* If there's an overflow page tail, write it too */
    if (my->mc_olen[toggle]) {
      wsize = my->mc_olen[toggle];
      ptr = my->mc_over[toggle];
      my->mc_olen[toggle] = 0;
      goto again;
    }
    my->mc_wlen[toggle] = 0;
    toggle ^= 1;
    /* Return the empty buffer to provider */
    my->mc_new--;
    pthread_cond_signal(&my->mc_cond);
  }
  pthread_mutex_unlock(&my->mc_mutex);
  return (THREAD_RET)0;
#undef DO_WRITE
}

/** Give buffer and/or #MDB_EOF to writer thread, await unused buffer.
 *
 * @param[in] my control structure.
 * @param[in] adjust (1 to hand off 1 buffer) | (MDB_EOF when ending).
 */
static int ESECT mdb_env_cthr_toggle(mdb_copy* my, int adjust) {
  pthread_mutex_lock(&my->mc_mutex);
  my->mc_new += adjust;
  pthread_cond_signal(&my->mc_cond);
  while (my->mc_new & 2) /* both buffers in use */
    pthread_cond_wait(&my->mc_cond, &my->mc_mutex);
  pthread_mutex_unlock(&my->mc_mutex);

  my->mc_toggle ^= (adjust & 1);
  /* Both threads reset mc_wlen, to be safe from threading errors */
  my->mc_wlen[my->mc_toggle] = 0;
  return my->mc_error;
}

/** Depth-first tree traversal for compacting copy.
 * @param[in] my control structure.
 * @param[in,out] pg database root.
 * @param[in] flags includes #F_DUPDATA if it is a sorted-duplicate sub-DB.
 */
static int ESECT mdb_env_cwalk(mdb_copy* my, pgno_t* pg, int flags) {
  MDB_cursor mc = {0};
  MDB_node* ni;
  MDB_page *mo, *mp, *leaf;
  char *buf, *ptr;
  int rc, toggle;
  unsigned int i;

  /* Empty DB, nothing to do */
  if (*pg == P_INVALID)
    return MDB_SUCCESS;

  mc.mc_snum = 1;
  mc.mc_txn = my->mc_txn;
  mc.mc_flags = my->mc_txn->mt_flags & (C_ORIG_RDONLY | C_WRITEMAP);

  rc = mdb_page_get(&mc, *pg, &mc.mc_pg[0], NULL);
  if (rc)
    return rc;
  rc = mdb_page_search_root(&mc, NULL, MDB_PS_FIRST);
  if (rc)
    return rc;

  /* Make cursor pages writable */
  buf = ptr = malloc(my->mc_env->me_psize * mc.mc_snum);
  if (buf == NULL)
    return ENOMEM;

  for (i = 0; i < mc.mc_top; i++) {
    mdb_page_copy((MDB_page*)ptr, mc.mc_pg[i], my->mc_env->me_psize);
    mc.mc_pg[i] = (MDB_page*)ptr;
    ptr += my->mc_env->me_psize;
  }

  /* This is writable space for a leaf page. Usually not needed. */
  leaf = (MDB_page*)ptr;

  toggle = my->mc_toggle;
  while (mc.mc_snum > 0) {
    unsigned n;
    mp = mc.mc_pg[mc.mc_top];
    n = NUMKEYS(mp);

    if (IS_LEAF(mp)) {
      if (!IS_LEAF2(mp) && !(flags & F_DUPDATA)) {
        for (i = 0; i < n; i++) {
          ni = NODEPTR(mp, i);
          if (ni->mn_flags & F_BIGDATA) {
            MDB_page* omp;
            pgno_t pg;

            /* Need writable leaf */
            if (mp != leaf) {
              mc.mc_pg[mc.mc_top] = leaf;
              mdb_page_copy(leaf, mp, my->mc_env->me_psize);
              mp = leaf;
              ni = NODEPTR(mp, i);
            }

            memcpy(&pg, NODEDATA(ni), sizeof(pg));
            memcpy(NODEDATA(ni), &my->mc_next_pgno, sizeof(pgno_t));
            rc = mdb_page_get(&mc, pg, &omp, NULL);
            if (rc)
              goto done;
            if (my->mc_wlen[toggle] >= MDB_WBUF) {
              rc = mdb_env_cthr_toggle(my, 1);
              if (rc)
                goto done;
              toggle = my->mc_toggle;
            }
            mo = (MDB_page*)(my->mc_wbuf[toggle] + my->mc_wlen[toggle]);
            memcpy(mo, omp, my->mc_env->me_psize);
            mo->mp_pgno = my->mc_next_pgno;
            my->mc_next_pgno += omp->mp_pages;
            my->mc_wlen[toggle] += my->mc_env->me_psize;
            if (omp->mp_pages > 1) {
              my->mc_olen[toggle] = my->mc_env->me_psize * (omp->mp_pages - 1);
              my->mc_over[toggle] = (char*)omp + my->mc_env->me_psize;
              rc = mdb_env_cthr_toggle(my, 1);
              if (rc)
                goto done;
              toggle = my->mc_toggle;
            }
          } else if (ni->mn_flags & F_SUBDATA) {
            MDB_db db;

            /* Need writable leaf */
            if (mp != leaf) {
              mc.mc_pg[mc.mc_top] = leaf;
              mdb_page_copy(leaf, mp, my->mc_env->me_psize);
              mp = leaf;
              ni = NODEPTR(mp, i);
            }

            memcpy(&db, NODEDATA(ni), sizeof(db));
            my->mc_toggle = toggle;
            rc = mdb_env_cwalk(my, &db.md_root, ni->mn_flags & F_DUPDATA);
            if (rc)
              goto done;
            toggle = my->mc_toggle;
            memcpy(NODEDATA(ni), &db, sizeof(db));
          }
        }
      }
    } else {
      mc.mc_ki[mc.mc_top]++;
      if (mc.mc_ki[mc.mc_top] < n) {
        pgno_t pg;
      again:
        ni = NODEPTR(mp, mc.mc_ki[mc.mc_top]);
        pg = NODEPGNO(ni);
        rc = mdb_page_get(&mc, pg, &mp, NULL);
        if (rc)
          goto done;
        mc.mc_top++;
        mc.mc_snum++;
        mc.mc_ki[mc.mc_top] = 0;
        if (IS_BRANCH(mp)) {
          /* Whenever we advance to a sibling branch page,
           * we must proceed all the way down to its first leaf.
           */
          mdb_page_copy(mc.mc_pg[mc.mc_top], mp, my->mc_env->me_psize);
          goto again;
        } else
          mc.mc_pg[mc.mc_top] = mp;
        continue;
      }
    }
    if (my->mc_wlen[toggle] >= MDB_WBUF) {
      rc = mdb_env_cthr_toggle(my, 1);
      if (rc)
        goto done;
      toggle = my->mc_toggle;
    }
    mo = (MDB_page*)(my->mc_wbuf[toggle] + my->mc_wlen[toggle]);
    mdb_page_copy(mo, mp, my->mc_env->me_psize);
    mo->mp_pgno = my->mc_next_pgno++;
    my->mc_wlen[toggle] += my->mc_env->me_psize;
    if (mc.mc_top) {
      /* Update parent if there is one */
      ni = NODEPTR(mc.mc_pg[mc.mc_top - 1], mc.mc_ki[mc.mc_top - 1]);
      SETPGNO(ni, mo->mp_pgno);
      mdb_cursor_pop(&mc);
    } else {
      /* Otherwise we're done */
      *pg = mo->mp_pgno;
      break;
    }
  }
done:
  free(buf);
  return rc;
}

/** Copy environment with compaction. */
static int ESECT mdb_env_copyfd1(MDB_env* env, HANDLE fd) {
  MDB_meta* mm;
  MDB_page* mp;
  mdb_copy my = {0};
  MDB_txn* txn = NULL;
  pthread_t thr;
  pgno_t root, new_root;
  int rc = MDB_SUCCESS;

#ifdef _WIN32
  if (!(my.mc_mutex = CreateMutex(NULL, FALSE, NULL)) ||
      !(my.mc_cond = CreateEvent(NULL, FALSE, FALSE, NULL))) {
    rc = ErrCode();
    goto done;
  }
  my.mc_wbuf[0] = _aligned_malloc(MDB_WBUF * 2, env->me_os_psize);
  if (my.mc_wbuf[0] == NULL) {
    /* _aligned_malloc() sets errno, but we use Windows error codes */
    rc = ERROR_NOT_ENOUGH_MEMORY;
    goto done;
  }
#else
  if ((rc = pthread_mutex_init(&my.mc_mutex, NULL)) != 0)
    return rc;
  if ((rc = pthread_cond_init(&my.mc_cond, NULL)) != 0)
    goto done2;
#ifdef HAVE_MEMALIGN
  my.mc_wbuf[0] = memalign(env->me_os_psize, MDB_WBUF * 2);
  if (my.mc_wbuf[0] == NULL) {
    rc = errno;
    goto done;
  }
#else
  {
    void* p;
    if ((rc = posix_memalign(&p, env->me_os_psize, MDB_WBUF * 2)) != 0)
      goto done;
    my.mc_wbuf[0] = p;
  }
#endif
#endif
  memset(my.mc_wbuf[0], 0, MDB_WBUF * 2);
  my.mc_wbuf[1] = my.mc_wbuf[0] + MDB_WBUF;
  my.mc_next_pgno = NUM_METAS;
  my.mc_env = env;
  my.mc_fd = fd;
  rc = THREAD_CREATE(thr, mdb_env_copythr, &my);
  if (rc)
    goto done;

  rc = mdb_txn_begin(env, NULL, MDB_RDONLY, &txn);
  if (rc)
    goto finish;

  mp = (MDB_page*)my.mc_wbuf[0];
  memset(mp, 0, NUM_METAS * env->me_psize);
  mp->mp_pgno = 0;
  mp->mp_flags = P_META;
  mm = (MDB_meta*)METADATA(mp);
  mdb_env_init_meta0(env, mm);
  mm->mm_address = env->me_metas[0]->mm_address;

  mp = (MDB_page*)(my.mc_wbuf[0] + env->me_psize);
  mp->mp_pgno = 1;
  mp->mp_flags = P_META;
  *(MDB_meta*)METADATA(mp) = *mm;
  mm = (MDB_meta*)METADATA(mp);

  /* Set metapage 1 with current main DB */
  root = new_root = txn->mt_dbs[MAIN_DBI].md_root;
  if (root != P_INVALID) {
    /* Count free pages + freeDB pages.  Subtract from last_pg
     * to find the new last_pg, which also becomes the new root.
     */
    MDB_ID freecount = 0;
    MDB_cursor mc;
    MDB_val key, data;
    mdb_cursor_init(&mc, txn, FREE_DBI, NULL);
    while ((rc = mdb_cursor_get(&mc, &key, &data, MDB_NEXT)) == 0)
      freecount += *(MDB_ID*)data.mv_data;
    if (rc != MDB_NOTFOUND)
      goto finish;
    freecount += txn->mt_dbs[FREE_DBI].md_branch_pages +
        txn->mt_dbs[FREE_DBI].md_leaf_pages +
        txn->mt_dbs[FREE_DBI].md_overflow_pages;

    new_root = txn->mt_next_pgno - 1 - freecount;
    mm->mm_last_pg = new_root;
    mm->mm_dbs[MAIN_DBI] = txn->mt_dbs[MAIN_DBI];
    mm->mm_dbs[MAIN_DBI].md_root = new_root;
  } else {
    /* When the DB is empty, handle it specially to
     * fix any breakage like page leaks from ITS#8174.
     */
    mm->mm_dbs[MAIN_DBI].md_flags = txn->mt_dbs[MAIN_DBI].md_flags;
  }
  if (root != P_INVALID || mm->mm_dbs[MAIN_DBI].md_flags) {
    mm->mm_txnid = 1; /* use metapage 1 */
  }

  my.mc_wlen[0] = env->me_psize * NUM_METAS;
  my.mc_txn = txn;
  rc = mdb_env_cwalk(&my, &root, 0);
  if (rc == MDB_SUCCESS && root != new_root) {
    rc = MDB_INCOMPATIBLE; /* page leak or corrupt DB */
  }

finish:
  if (rc)
    my.mc_error = rc;
  mdb_env_cthr_toggle(&my, 1 | MDB_EOF);
  rc = THREAD_FINISH(thr);
  _mdb_txn_abort(txn);

done:
#ifdef _WIN32
  if (my.mc_wbuf[0])
    _aligned_free(my.mc_wbuf[0]);
  if (my.mc_cond)
    CloseHandle(my.mc_cond);
  if (my.mc_mutex)
    CloseHandle(my.mc_mutex);
#else
  free(my.mc_wbuf[0]);
  pthread_cond_destroy(&my.mc_cond);
done2:
  pthread_mutex_destroy(&my.mc_mutex);
#endif
  return rc ? rc : my.mc_error;
}

/** Copy environment as-is. */
static int ESECT mdb_env_copyfd0(MDB_env* env, HANDLE fd) {
  MDB_txn* txn = NULL;
  mdb_mutexref_t wmutex = NULL;
  int rc;
  mdb_size_t wsize, w3;
  char* ptr;
#ifdef _WIN32
  DWORD len, w2;
#define DO_WRITE(rc, fd, ptr, w2, len) rc = WriteFile(fd, ptr, w2, &len, NULL)
#else
  ssize_t len;
  size_t w2;
#define DO_WRITE(rc, fd, ptr, w2, len) \
  len = write(fd, ptr, w2);            \
  rc = (len >= 0)
#endif

  /* Do the lock/unlock of the reader mutex before starting the
   * write txn.  Otherwise other read txns could block writers.
   */
  rc = mdb_txn_begin(env, NULL, MDB_RDONLY, &txn);
  if (rc)
    return rc;

  if (env->me_txns) {
    /* We must start the actual read txn after blocking writers */
    mdb_txn_end(txn, MDB_END_RESET_TMP);

    /* Temporarily block writers until we snapshot the meta pages */
    wmutex = env->me_wmutex;
    if (LOCK_MUTEX(rc, env, wmutex))
      goto leave;

    rc = mdb_txn_renew0(txn);
    if (rc) {
      UNLOCK_MUTEX(wmutex);
      goto leave;
    }
  }

  wsize = env->me_psize * NUM_METAS;
  ptr = env->me_map;
  w2 = wsize;
  while (w2 > 0) {
    DO_WRITE(rc, fd, ptr, w2, len);
    if (!rc) {
      rc = ErrCode();
      break;
    } else if (len > 0) {
      rc = MDB_SUCCESS;
      ptr += len;
      w2 -= len;
      continue;
    } else {
      /* Non-blocking or async handles are not supported */
      rc = EIO;
      break;
    }
  }
  if (wmutex)
    UNLOCK_MUTEX(wmutex);

  if (rc)
    goto leave;

  w3 = txn->mt_next_pgno * env->me_psize;
  {
    mdb_size_t fsize = 0;
    if ((rc = mdb_fsize(env->me_fd, &fsize)))
      goto leave;
    if (w3 > fsize)
      w3 = fsize;
  }
  wsize = w3 - wsize;
  while (wsize > 0) {
    if (wsize > MAX_WRITE)
      w2 = MAX_WRITE;
    else
      w2 = wsize;
    DO_WRITE(rc, fd, ptr, w2, len);
    if (!rc) {
      rc = ErrCode();
      break;
    } else if (len > 0) {
      rc = MDB_SUCCESS;
      ptr += len;
      wsize -= len;
      continue;
    } else {
      rc = EIO;
      break;
    }
  }

leave:
  _mdb_txn_abort(txn);
  return rc;
}

int ESECT mdb_env_copyfd2(MDB_env* env, HANDLE fd, unsigned int flags) {
  if (flags & MDB_CP_COMPACT)
    return mdb_env_copyfd1(env, fd);
  else
    return mdb_env_copyfd0(env, fd);
}

int ESECT mdb_env_copyfd(MDB_env* env, HANDLE fd) {
  return mdb_env_copyfd2(env, fd, 0);
}

int ESECT mdb_env_copy2(MDB_env* env, const char* path, unsigned int flags) {
  int rc;
  MDB_name fname;
  HANDLE newfd = INVALID_HANDLE_VALUE;

  rc = mdb_fname_init(path, env->me_flags | MDB_NOLOCK, &fname);
  if (rc == MDB_SUCCESS) {
    rc = mdb_fopen(env, &fname, MDB_O_COPY, 0666, &newfd);
    mdb_fname_destroy(fname);
  }
  if (rc == MDB_SUCCESS) {
    rc = mdb_env_copyfd2(env, newfd, flags);
    if (close(newfd) < 0 && rc == MDB_SUCCESS)
      rc = ErrCode();
  }
  return rc;
}

int ESECT mdb_env_copy(MDB_env* env, const char* path) {
  return mdb_env_copy2(env, path, 0);
}

int ESECT mdb_env_set_flags(MDB_env* env, unsigned int flag, int onoff) {
  if (flag & ~CHANGEABLE)
    return EINVAL;
  if (onoff)
    env->me_flags |= flag;
  else
    env->me_flags &= ~flag;
  return MDB_SUCCESS;
}

int ESECT mdb_env_get_flags(MDB_env* env, unsigned int* arg) {
  if (!env || !arg)
    return EINVAL;

  *arg = env->me_flags & (CHANGEABLE | CHANGELESS);
  return MDB_SUCCESS;
}

int ESECT mdb_env_set_userctx(MDB_env* env, void* ctx) {
  if (!env)
    return EINVAL;
  env->me_userctx = ctx;
  return MDB_SUCCESS;
}

void* ESECT mdb_env_get_userctx(MDB_env* env) {
  return env ? env->me_userctx : NULL;
}

int ESECT mdb_env_set_assert(MDB_env* env, MDB_assert_func* func) {
  if (!env)
    return EINVAL;
#ifndef NDEBUG
  env->me_assert_func = func;
#endif
  return MDB_SUCCESS;
}

int ESECT mdb_env_get_path(MDB_env* env, const char** arg) {
  if (!env || !arg)
    return EINVAL;

  *arg = env->me_path;
  return MDB_SUCCESS;
}

int ESECT mdb_env_get_fd(MDB_env* env, mdb_filehandle_t* arg) {
  if (!env || !arg)
    return EINVAL;

  *arg = env->me_fd;
  return MDB_SUCCESS;
}

/** Common code for #mdb_stat() and #mdb_env_stat().
 * @param[in] env the environment to operate in.
 * @param[in] db the #MDB_db record containing the stats to return.
 * @param[out] arg the address of an #MDB_stat structure to receive the stats.
 * @return 0, this function always succeeds.
 */
static int ESECT 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 ESECT mdb_env_stat(MDB_env* env, MDB_stat* arg) {
  MDB_meta* meta;

  if (env == NULL || arg == NULL)
    return EINVAL;

  meta = mdb_env_pick_meta(env);

  return mdb_stat0(env, &meta->mm_dbs[MAIN_DBI], arg);
}

int ESECT mdb_env_info(MDB_env* env, MDB_envinfo* arg) {
  MDB_meta* meta;

  if (env == NULL || arg == NULL)
    return EINVAL;

  meta = mdb_env_pick_meta(env);
  arg->me_mapaddr = meta->mm_address;
  arg->me_last_pgno = meta->mm_last_pg;
  arg->me_last_txnid = meta->mm_txnid;

  arg->me_mapsize = env->me_mapsize;
  arg->me_maxreaders = env->me_maxreaders;
  arg->me_numreaders = env->me_txns ? env->me_txns->mti_numreaders : 0;
  return MDB_SUCCESS;
}

/** Set the default comparison functions for a database.
 * Called immediately after a database is opened to set the defaults.
 * The user can then override them with #mdb_set_compare() or
 * #mdb_set_dupsort().
 * @param[in] txn A transaction handle returned by #mdb_txn_begin()
 * @param[in] dbi A database handle returned by #mdb_dbi_open()
 */
static void mdb_default_cmp(MDB_txn* txn, MDB_dbi dbi) {
  uint16_t f = txn->mt_dbs[dbi].md_flags;

  txn->mt_dbxs[dbi].md_cmp = (f & MDB_REVERSEKEY) ? mdb_cmp_memnr
      : (f & MDB_INTEGERKEY)                      ? mdb_cmp_cint
                                                  : mdb_cmp_memn;

  txn->mt_dbxs[dbi].md_dcmp = !(f & MDB_DUPSORT)
      ? 0
      : ((f & MDB_INTEGERDUP)
             ? ((f & MDB_DUPFIXED) ? mdb_cmp_int : mdb_cmp_cint)
             : ((f & MDB_REVERSEDUP) ? mdb_cmp_memnr : mdb_cmp_memn));
}

int mdb_dbi_open(
    MDB_txn* txn,
    const char* name,
    unsigned int flags,
    MDB_dbi* dbi) {
  MDB_val key, data;
  MDB_dbi i;
  MDB_cursor mc;
  MDB_db dummy;
  int rc, dbflag, exact;
  unsigned int unused = 0, seq;
  char* namedup;
  size_t len;

  if (flags & ~VALID_FLAGS)
    return EINVAL;
  if (txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  /* main DB? */
  if (!name) {
    *dbi = MAIN_DBI;
    if (flags & PERSISTENT_FLAGS) {
      uint16_t f2 = flags & PERSISTENT_FLAGS;
      /* make sure flag changes get committed */
      if ((txn->mt_dbs[MAIN_DBI].md_flags | f2) !=
          txn->mt_dbs[MAIN_DBI].md_flags) {
        txn->mt_dbs[MAIN_DBI].md_flags |= f2;
        txn->mt_flags |= MDB_TXN_DIRTY;
      }
    }
    mdb_default_cmp(txn, MAIN_DBI);
    MDB_TRACE(("%p, (null), %u = %u", txn, flags, 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 = CORE_DBS; i < txn->mt_numdbs; i++) {
    if (!txn->mt_dbxs[i].md_name.mv_size) {
      /* Remember this free slot */
      if (!unused)
        unused = i;
      continue;
    }
    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 no free slot and max hit, fail */
  if (!unused && txn->mt_numdbs >= txn->mt_env->me_maxdbs)
    return MDB_DBS_FULL;

  /* Cannot mix named databases with some mainDB flags */
  if (txn->mt_dbs[MAIN_DBI].md_flags & (MDB_DUPSORT | MDB_INTEGERKEY))
    return (flags & MDB_CREATE) ? MDB_INCOMPATIBLE : MDB_NOTFOUND;

  /* Find the DB info */
  dbflag = DB_NEW | DB_VALID | DB_USRVALID;
  exact = 0;
  key.mv_size = len;
  key.mv_data = (void*)name;
  mdb_cursor_init(&mc, txn, MAIN_DBI, NULL);
  rc = mdb_cursor_set(&mc, &key, &data, MDB_SET, &exact);
  if (rc == MDB_SUCCESS) {
    /* make sure this is actually a DB */
    MDB_node* node = NODEPTR(mc.mc_pg[mc.mc_top], mc.mc_ki[mc.mc_top]);
    if ((node->mn_flags & (F_DUPDATA | F_SUBDATA)) != F_SUBDATA)
      return MDB_INCOMPATIBLE;
  } else {
    if (rc != MDB_NOTFOUND || !(flags & MDB_CREATE))
      return rc;
    if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY))
      return EACCES;
  }

  /* Done here so we cannot fail after creating a new DB */
  if ((namedup = strdup(name)) == NULL)
    return ENOMEM;

  if (rc) {
    /* MDB_NOTFOUND and MDB_CREATE: Create new DB */
    data.mv_size = sizeof(MDB_db);
    data.mv_data = &dummy;
    memset(&dummy, 0, sizeof(dummy));
    dummy.md_root = P_INVALID;
    dummy.md_flags = flags & PERSISTENT_FLAGS;
    WITH_CURSOR_TRACKING(mc, rc = _mdb_cursor_put(&mc, &key, &data, F_SUBDATA));
    dbflag |= DB_DIRTY;
  }

  if (rc) {
    free(namedup);
  } else {
    /* Got info, register DBI in this txn */
    unsigned int slot = unused ? unused : txn->mt_numdbs;
    txn->mt_dbxs[slot].md_name.mv_data = namedup;
    txn->mt_dbxs[slot].md_name.mv_size = len;
    txn->mt_dbxs[slot].md_rel = NULL;
    txn->mt_dbflags[slot] = dbflag;
    /* txn-> and env-> are the same in read txns, use
     * tmp variable to avoid undefined assignment
     */
    seq = ++txn->mt_env->me_dbiseqs[slot];
    txn->mt_dbiseqs[slot] = seq;

    memcpy(&txn->mt_dbs[slot], data.mv_data, sizeof(MDB_db));
    *dbi = slot;
    mdb_default_cmp(txn, slot);
    if (!unused) {
      txn->mt_numdbs++;
    }
    MDB_TRACE(("%p, %s, %u = %u", txn, name, flags, slot));
  }

  return rc;
}

int ESECT mdb_stat(MDB_txn* txn, MDB_dbi dbi, MDB_stat* arg) {
  if (!arg || !TXN_DBI_EXIST(txn, dbi, DB_VALID))
    return EINVAL;

  if (txn->mt_flags & MDB_TXN_BLOCKED)
    return MDB_BAD_TXN;

  if (txn->mt_dbflags[dbi] & DB_STALE) {
    MDB_cursor mc;
    MDB_xcursor mx;
    /* Stale, must read the DB's root. cursor_init does it for us. */
    mdb_cursor_init(&mc, txn, dbi, &mx);
  }
  return mdb_stat0(txn->mt_env, &txn->mt_dbs[dbi], arg);
}

void mdb_dbi_close(MDB_env* env, MDB_dbi dbi) {
  char* ptr;
  if (dbi < CORE_DBS || dbi >= env->me_maxdbs)
    return;
  ptr = env->me_dbxs[dbi].md_name.mv_data;
  /* If there was no name, this was already closed */
  if (ptr) {
    MDB_TRACE(("%p, %u", env, dbi));
    env->me_dbxs[dbi].md_name.mv_data = NULL;
    env->me_dbxs[dbi].md_name.mv_size = 0;
    env->me_dbflags[dbi] = 0;
    env->me_dbiseqs[dbi]++;
    free(ptr);
  }
}

int mdb_dbi_flags(MDB_txn* txn, MDB_dbi dbi, unsigned int* flags) {
  /* We could return the flags for the FREE_DBI too but what's the point? */
  if (!TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;
  *flags = txn->mt_dbs[dbi].md_flags & PERSISTENT_FLAGS;
  return MDB_SUCCESS;
}

/** Add all the DB's pages to the free list.
 * @param[in] mc Cursor on the DB to free.
 * @param[in] subs non-Zero to check for sub-DBs in this DB.
 * @return 0 on success, non-zero on failure.
 */
static int mdb_drop0(MDB_cursor* mc, int subs) {
  int rc;

  rc = mdb_page_search(mc, NULL, MDB_PS_FIRST);
  if (rc == MDB_SUCCESS) {
    MDB_txn* txn = mc->mc_txn;
    MDB_node* ni;
    MDB_cursor mx;
    unsigned int i;

    /* DUPSORT sub-DBs have no ovpages/DBs. Omit scanning leaves.
     * This also avoids any P_LEAF2 pages, which have no nodes.
     * Also if the DB doesn't have sub-DBs and has no overflow
     * pages, omit scanning leaves.
     */
    if ((mc->mc_flags & C_SUB) || (!subs && !mc->mc_db->md_overflow_pages))
      mdb_cursor_pop(mc);

    mdb_cursor_copy(mc, &mx);
#ifdef MDB_VL32
    /* bump refcount for mx's pages */
    for (i = 0; i < mc->mc_snum; i++)
      mdb_page_get(&mx, mc->mc_pg[i]->mp_pgno, &mx.mc_pg[i], NULL);
#endif
    while (mc->mc_snum > 0) {
      MDB_page* mp = mc->mc_pg[mc->mc_top];
      unsigned n = NUMKEYS(mp);
      if (IS_LEAF(mp)) {
        for (i = 0; i < n; i++) {
          ni = NODEPTR(mp, i);
          if (ni->mn_flags & F_BIGDATA) {
            MDB_page* omp;
            pgno_t pg;
            memcpy(&pg, NODEDATA(ni), sizeof(pg));
            rc = mdb_page_get(mc, pg, &omp, NULL);
            if (rc != 0)
              goto done;
            mdb_cassert(mc, IS_OVERFLOW(omp));
            rc = mdb_midl_append_range(&txn->mt_free_pgs, pg, omp->mp_pages);
            if (rc)
              goto done;
            mc->mc_db->md_overflow_pages -= omp->mp_pages;
            if (!mc->mc_db->md_overflow_pages && !subs)
              break;
          } else if (subs && (ni->mn_flags & F_SUBDATA)) {
            mdb_xcursor_init1(mc, ni);
            rc = mdb_drop0(&mc->mc_xcursor->mx_cursor, 0);
            if (rc)
              goto done;
          }
        }
        if (!subs && !mc->mc_db->md_overflow_pages)
          goto pop;
      } else {
        if ((rc = mdb_midl_need(&txn->mt_free_pgs, n)) != 0)
          goto done;
        for (i = 0; i < n; i++) {
          pgno_t pg;
          ni = NODEPTR(mp, i);
          pg = NODEPGNO(ni);
          /* free it */
          mdb_midl_xappend(txn->mt_free_pgs, pg);
        }
      }
      if (!mc->mc_top)
        break;
      mc->mc_ki[mc->mc_top] = i;
      rc = mdb_cursor_sibling(mc, 1);
      if (rc) {
        if (rc != MDB_NOTFOUND)
          goto done;
        /* no more siblings, go back to beginning
         * of previous level.
         */
      pop:
        mdb_cursor_pop(mc);
        mc->mc_ki[0] = 0;
        for (i = 1; i < mc->mc_snum; i++) {
          mc->mc_ki[i] = 0;
          mc->mc_pg[i] = mx.mc_pg[i];
        }
      }
    }
    /* free it */
    rc = mdb_midl_append(&txn->mt_free_pgs, mc->mc_db->md_root);
  done:
    if (rc)
      txn->mt_flags |= MDB_TXN_ERROR;
    /* drop refcount for mx's pages */
    MDB_CURSOR_UNREF(&mx, 0);
  } else if (rc == MDB_NOTFOUND) {
    rc = MDB_SUCCESS;
  }
  mc->mc_flags &= ~C_INITIALIZED;
  return rc;
}

int mdb_drop(MDB_txn* txn, MDB_dbi dbi, int del) {
  MDB_cursor *mc, *m2;
  int rc;

  if ((unsigned)del > 1 || !TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;

  if (F_ISSET(txn->mt_flags, MDB_TXN_RDONLY))
    return EACCES;

  if (TXN_DBI_CHANGED(txn, dbi))
    return MDB_BAD_DBI;

  rc = mdb_cursor_open(txn, dbi, &mc);
  if (rc)
    return rc;

  MDB_TRACE(("%u, %d", dbi, del));
  rc = mdb_drop0(mc, mc->mc_db->md_flags & MDB_DUPSORT);
  /* Invalidate the dropped DB's cursors */
  for (m2 = txn->mt_cursors[dbi]; m2; m2 = m2->mc_next)
    m2->mc_flags &= ~(C_INITIALIZED | C_EOF);
  if (rc)
    goto leave;

  /* Can't delete the main DB */
  if (del && dbi >= CORE_DBS) {
    rc = mdb_del0(txn, MAIN_DBI, &mc->mc_dbx->md_name, NULL, F_SUBDATA);
    if (!rc) {
      txn->mt_dbflags[dbi] = DB_STALE;
      mdb_dbi_close(txn->mt_env, dbi);
    } else {
      txn->mt_flags |= MDB_TXN_ERROR;
    }
  } else {
    /* reset the DB record, mark it dirty */
    txn->mt_dbflags[dbi] |= DB_DIRTY;
    txn->mt_dbs[dbi].md_depth = 0;
    txn->mt_dbs[dbi].md_branch_pages = 0;
    txn->mt_dbs[dbi].md_leaf_pages = 0;
    txn->mt_dbs[dbi].md_overflow_pages = 0;
    txn->mt_dbs[dbi].md_entries = 0;
    txn->mt_dbs[dbi].md_root = P_INVALID;

    txn->mt_flags |= MDB_TXN_DIRTY;
  }
leave:
  mdb_cursor_close(mc);
  return rc;
}

int mdb_set_compare(MDB_txn* txn, MDB_dbi dbi, MDB_cmp_func* cmp) {
  if (!TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    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_DBI_EXIST(txn, dbi, DB_USRVALID))
    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_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;

  txn->mt_dbxs[dbi].md_rel = rel;
  return MDB_SUCCESS;
}

int mdb_set_relctx(MDB_txn* txn, MDB_dbi dbi, void* ctx) {
  if (!TXN_DBI_EXIST(txn, dbi, DB_USRVALID))
    return EINVAL;

  txn->mt_dbxs[dbi].md_relctx = ctx;
  return MDB_SUCCESS;
}

int ESECT mdb_env_get_maxkeysize(MDB_env* env) {
  return ENV_MAXKEY(env);
}

int ESECT mdb_reader_list(MDB_env* env, MDB_msg_func* func, void* ctx) {
  unsigned int i, rdrs;
  MDB_reader* mr;
  char buf[64];
  int rc = 0, first = 1;

  if (!env || !func)
    return -1;
  if (!env->me_txns) {
    return func("(no reader locks)\n", ctx);
  }
  rdrs = env->me_txns->mti_numreaders;
  mr = env->me_txns->mti_readers;
  for (i = 0; i < rdrs; i++) {
    if (mr[i].mr_pid) {
      txnid_t txnid = mr[i].mr_txnid;
      snprintf(
          buf,
          sizeof(buf),
          txnid == (txnid_t)-1 ? "%10d %" Z "x -\n" : "%10d %" Z "x %" Yu "\n",
          (int)mr[i].mr_pid,
          (size_t)mr[i].mr_tid,
          txnid);
      if (first) {
        first = 0;
        rc = func("    pid     thread     txnid\n", ctx);
        if (rc < 0)
          break;
      }
      rc = func(buf, ctx);
      if (rc < 0)
        break;
    }
  }
  if (first) {
    rc = func("(no active readers)\n", ctx);
  }
  return rc;
}

/** Insert pid into list if not already present.
 * return -1 if already present.
 */
static int ESECT mdb_pid_insert(MDB_PID_T* ids, MDB_PID_T pid) {
  /* binary search of pid in list */
  unsigned base = 0;
  unsigned cursor = 1;
  int val = 0;
  unsigned n = ids[0];

  while (0 < n) {
    unsigned pivot = n >> 1;
    cursor = base + pivot + 1;
    val = pid - ids[cursor];

    if (val < 0) {
      n = pivot;

    } else if (val > 0) {
      base = cursor;
      n -= pivot + 1;

    } else {
      /* found, so it's a duplicate */
      return -1;
    }
  }

  if (val > 0) {
    ++cursor;
  }
  ids[0]++;
  for (n = ids[0]; n > cursor; n--)
    ids[n] = ids[n - 1];
  ids[n] = pid;
  return 0;
}

int ESECT mdb_reader_check(MDB_env* env, int* dead) {
  if (!env)
    return EINVAL;
  if (dead)
    *dead = 0;
  return env->me_txns ? mdb_reader_check0(env, 0, dead) : MDB_SUCCESS;
}

/** As #mdb_reader_check(). \b rlocked is set if caller locked #me_rmutex. */
static int ESECT mdb_reader_check0(MDB_env* env, int rlocked, int* dead) {
  mdb_mutexref_t rmutex = rlocked ? NULL : env->me_rmutex;
  unsigned int i, j, rdrs;
  MDB_reader* mr;
  MDB_PID_T *pids, pid;
  int rc = MDB_SUCCESS, count = 0;

  rdrs = env->me_txns->mti_numreaders;
  pids = malloc((rdrs + 1) * sizeof(MDB_PID_T));
  if (!pids)
    return ENOMEM;
  pids[0] = 0;
  mr = env->me_txns->mti_readers;
  for (i = 0; i < rdrs; i++) {
    pid = mr[i].mr_pid;
    if (pid && pid != env->me_pid) {
      if (mdb_pid_insert(pids, pid) == 0) {
        if (!mdb_reader_pid(env, Pidcheck, pid)) {
          /* Stale reader found */
          j = i;
          if (rmutex) {
            if ((rc = LOCK_MUTEX0(rmutex)) != 0) {
              if ((rc = mdb_mutex_failed(env, rmutex, rc)))
                break;
              rdrs = 0; /* the above checked all readers */
            } else {
              /* Recheck, a new process may have reused pid */
              if (mdb_reader_pid(env, Pidcheck, pid))
                j = rdrs;
            }
          }
          for (; j < rdrs; j++)
            if (mr[j].mr_pid == pid) {
              DPRINTF(
                  ("clear stale reader pid %u txn %" Yd,
                   (unsigned)pid,
                   mr[j].mr_txnid));
              mr[j].mr_pid = 0;
              count++;
            }
          if (rmutex)
            UNLOCK_MUTEX(rmutex);
        }
      }
    }
  }
  free(pids);
  if (dead)
    *dead = count;
  return rc;
}

#ifdef MDB_ROBUST_SUPPORTED
/** Handle #LOCK_MUTEX0() failure.
 * Try to repair the lock file if the mutex owner died.
 * @param[in] env	the environment handle
 * @param[in] mutex	LOCK_MUTEX0() mutex
 * @param[in] rc	LOCK_MUTEX0() error (nonzero)
 * @return 0 on success with the mutex locked, or an error code on failure.
 */
static int ESECT mdb_mutex_failed(MDB_env* env, mdb_mutexref_t mutex, int rc) {
  int rlocked, rc2;
  MDB_meta* meta;

  if (rc == MDB_OWNERDEAD) {
    /* We own the mutex. Clean up after dead previous owner. */
    rc = MDB_SUCCESS;
    rlocked = (mutex == env->me_rmutex);
    if (!rlocked) {
      /* Keep mti_txnid updated, otherwise next writer can
       * overwrite data which latest meta page refers to.
       */
      meta = mdb_env_pick_meta(env);
      env->me_txns->mti_txnid = meta->mm_txnid;
      /* env is hosed if the dead thread was ours */
      if (env->me_txn) {
        env->me_flags |= MDB_FATAL_ERROR;
        env->me_txn = NULL;
        rc = MDB_PANIC;
      }
    }
    DPRINTF(
        ("%cmutex owner died, %s",
         (rlocked ? 'r' : 'w'),
         (rc ? "this process' env is hosed" : "recovering")));
    rc2 = mdb_reader_check0(env, rlocked, NULL);
    if (rc2 == 0)
      rc2 = mdb_mutex_consistent(mutex);
    if (rc || (rc = rc2)) {
      DPRINTF(("LOCK_MUTEX recovery failed, %s", mdb_strerror(rc)));
      UNLOCK_MUTEX(mutex);
    }
  } else {
#ifdef _WIN32
    rc = ErrCode();
#endif
    DPRINTF(("LOCK_MUTEX failed, %s", mdb_strerror(rc)));
  }

  return rc;
}
#endif /* MDB_ROBUST_SUPPORTED */

#if defined(_WIN32)
/** Convert \b src to new wchar_t[] string with room for \b xtra extra chars */
static int ESECT utf8_to_utf16(const char* src, MDB_name* dst, int xtra) {
  int rc, need = 0;
  wchar_t* result = NULL;
  for (;;) { /* malloc result, then fill it in */
    need = MultiByteToWideChar(CP_UTF8, 0, src, -1, result, need);
    if (!need) {
      rc = ErrCode();
      free(result);
      return rc;
    }
    if (!result) {
      result = malloc(sizeof(wchar_t) * (need + xtra));
      if (!result)
        return ENOMEM;
      continue;
    }
    dst->mn_alloced = 1;
    dst->mn_len = need - 1;
    dst->mn_val = result;
    return MDB_SUCCESS;
  }
}
#endif /* defined(_WIN32) */
/** @} */