src/physfs.c

/**
 * PhysicsFS; a portable, flexible file i/o abstraction.
 *
 * Documentation is in physfs.h. It's verbose, honest.  :)
 *
 * Please see the file LICENSE.txt in the source's root directory.
 *
 *  This file written by Ryan C. Gordon.
 */

/* !!! FIXME: ERR_PAST_EOF shouldn't trigger for reads. Just return zero. */
/* !!! FIXME: use snprintf(), not sprintf(). */

#define __PHYSICSFS_INTERNAL__
#include "physfs_internal.h"


typedef struct __PHYSFS_DIRHANDLE__
{
    void *opaque;  /* Instance data unique to the archiver. */
    char *dirName;  /* Path to archive in platform-dependent notation. */
    char *mountPoint; /* Mountpoint in virtual file tree. */
    const PHYSFS_Archiver *funcs;  /* Ptr to archiver info for this handle. */
    struct __PHYSFS_DIRHANDLE__ *next;  /* linked list stuff. */
} DirHandle;


typedef struct __PHYSFS_FILEHANDLE__
{
    PHYSFS_Io *io;  /* Instance data unique to the archiver for this file. */
    PHYSFS_uint8 forReading; /* Non-zero if reading, zero if write/append */
    const DirHandle *dirHandle;  /* Archiver instance that created this */
    PHYSFS_uint8 *buffer;  /* Buffer, if set (NULL otherwise). Don't touch! */
    PHYSFS_uint32 bufsize;  /* Bufsize, if set (0 otherwise). Don't touch! */
    PHYSFS_uint32 buffill;  /* Buffer fill size. Don't touch! */
    PHYSFS_uint32 bufpos;  /* Buffer position. Don't touch! */
    struct __PHYSFS_FILEHANDLE__ *next;  /* linked list stuff. */
} FileHandle;


typedef struct __PHYSFS_ERRSTATETYPE__
{
    void *tid;
    PHYSFS_ErrorCode code;
    struct __PHYSFS_ERRSTATETYPE__ *next;
} ErrState;


/* The various i/o drivers...some of these may not be compiled in. */
extern const PHYSFS_Archiver __PHYSFS_Archiver_ZIP;
extern const PHYSFS_Archiver __PHYSFS_Archiver_LZMA;
extern const PHYSFS_Archiver __PHYSFS_Archiver_GRP;
extern const PHYSFS_Archiver __PHYSFS_Archiver_QPAK;
extern const PHYSFS_Archiver __PHYSFS_Archiver_HOG;
extern const PHYSFS_Archiver __PHYSFS_Archiver_MVL;
extern const PHYSFS_Archiver __PHYSFS_Archiver_WAD;
extern const PHYSFS_Archiver __PHYSFS_Archiver_SLB;
extern const PHYSFS_Archiver __PHYSFS_Archiver_DIR;
extern const PHYSFS_Archiver __PHYSFS_Archiver_ISO9660;

static const PHYSFS_Archiver * const staticArchivers[] =
{
#if PHYSFS_SUPPORTS_ZIP
    &__PHYSFS_Archiver_ZIP,
#endif
#if PHYSFS_SUPPORTS_7Z
    &__PHYSFS_Archiver_LZMA,
#endif
#if PHYSFS_SUPPORTS_GRP
    &__PHYSFS_Archiver_GRP,
#endif
#if PHYSFS_SUPPORTS_QPAK
    &__PHYSFS_Archiver_QPAK,
#endif
#if PHYSFS_SUPPORTS_HOG
    &__PHYSFS_Archiver_HOG,
#endif
#if PHYSFS_SUPPORTS_MVL
    &__PHYSFS_Archiver_MVL,
#endif
#if PHYSFS_SUPPORTS_WAD
    &__PHYSFS_Archiver_WAD,
#endif
#if PHYSFS_SUPPORTS_SLB
    &__PHYSFS_Archiver_SLB,
#endif
#if PHYSFS_SUPPORTS_ISO9660
    &__PHYSFS_Archiver_ISO9660,
#endif
    NULL
};


/* General PhysicsFS state ... */
static int initialized = 0;
static ErrState *errorStates = NULL;
static DirHandle *searchPath = NULL;
static DirHandle *writeDir = NULL;
static FileHandle *openWriteList = NULL;
static FileHandle *openReadList = NULL;
static char *baseDir = NULL;
static char *userDir = NULL;
static char *prefDir = NULL;
static int allowSymLinks = 0;
static const PHYSFS_Archiver **archivers = NULL;
static const PHYSFS_ArchiveInfo **archiveInfo = NULL;
static volatile size_t numArchivers = 0;

/* mutexes ... */
static void *errorLock = NULL;     /* protects error message list.        */
static void *stateLock = NULL;     /* protects other PhysFS static state. */

/* allocator ... */
static int externalAllocator = 0;
PHYSFS_Allocator allocator;


/* PHYSFS_Io implementation for i/o to physical filesystem... */

/* !!! FIXME: maybe refcount the paths in a string pool? */
typedef struct __PHYSFS_NativeIoInfo
{
    void *handle;
    const char *path;
    int mode;   /* 'r', 'w', or 'a' */
} NativeIoInfo;

static PHYSFS_sint64 nativeIo_read(PHYSFS_Io *io, void *buf, PHYSFS_uint64 len)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    return __PHYSFS_platformRead(info->handle, buf, len);
} /* nativeIo_read */

static PHYSFS_sint64 nativeIo_write(PHYSFS_Io *io, const void *buffer,
                                    PHYSFS_uint64 len)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    return __PHYSFS_platformWrite(info->handle, buffer, len);
} /* nativeIo_write */

static int nativeIo_seek(PHYSFS_Io *io, PHYSFS_uint64 offset)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    return __PHYSFS_platformSeek(info->handle, offset);
} /* nativeIo_seek */

static PHYSFS_sint64 nativeIo_tell(PHYSFS_Io *io)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    return __PHYSFS_platformTell(info->handle);
} /* nativeIo_tell */

static PHYSFS_sint64 nativeIo_length(PHYSFS_Io *io)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    return __PHYSFS_platformFileLength(info->handle);
} /* nativeIo_length */

static PHYSFS_Io *nativeIo_duplicate(PHYSFS_Io *io)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    return __PHYSFS_createNativeIo(info->path, info->mode);
} /* nativeIo_duplicate */

static int nativeIo_flush(PHYSFS_Io *io)
{
    return __PHYSFS_platformFlush(io->opaque);
} /* nativeIo_flush */

static void nativeIo_destroy(PHYSFS_Io *io)
{
    NativeIoInfo *info = (NativeIoInfo *) io->opaque;
    __PHYSFS_platformClose(info->handle);
    allocator.Free((void *) info->path);
    allocator.Free(info);
    allocator.Free(io);
} /* nativeIo_destroy */

static const PHYSFS_Io __PHYSFS_nativeIoInterface =
{
    CURRENT_PHYSFS_IO_API_VERSION, NULL,
    nativeIo_read,
    nativeIo_write,
    nativeIo_seek,
    nativeIo_tell,
    nativeIo_length,
    nativeIo_duplicate,
    nativeIo_flush,
    nativeIo_destroy
};

PHYSFS_Io *__PHYSFS_createNativeIo(const char *path, const int mode)
{
    PHYSFS_Io *io = NULL;
    NativeIoInfo *info = NULL;
    void *handle = NULL;
    char *pathdup = NULL;

    assert((mode == 'r') || (mode == 'w') || (mode == 'a'));

    io = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
    GOTO_IF_MACRO(!io, PHYSFS_ERR_OUT_OF_MEMORY, createNativeIo_failed);
    info = (NativeIoInfo *) allocator.Malloc(sizeof (NativeIoInfo));
    GOTO_IF_MACRO(!info, PHYSFS_ERR_OUT_OF_MEMORY, createNativeIo_failed);
    pathdup = (char *) allocator.Malloc(strlen(path) + 1);
    GOTO_IF_MACRO(!pathdup, PHYSFS_ERR_OUT_OF_MEMORY, createNativeIo_failed);

    if (mode == 'r')
        handle = __PHYSFS_platformOpenRead(path);
    else if (mode == 'w')
        handle = __PHYSFS_platformOpenWrite(path);
    else if (mode == 'a')
        handle = __PHYSFS_platformOpenAppend(path);

    GOTO_IF_MACRO(!handle, ERRPASS, createNativeIo_failed);

    strcpy(pathdup, path);
    info->handle = handle;
    info->path = pathdup;
    info->mode = mode;
    memcpy(io, &__PHYSFS_nativeIoInterface, sizeof (*io));
    io->opaque = info;
    return io;

createNativeIo_failed:
    if (handle != NULL) __PHYSFS_platformClose(handle);
    if (pathdup != NULL) allocator.Free(pathdup);
    if (info != NULL) allocator.Free(info);
    if (io != NULL) allocator.Free(io);
    return NULL;
} /* __PHYSFS_createNativeIo */


/* PHYSFS_Io implementation for i/o to a memory buffer... */

typedef struct __PHYSFS_MemoryIoInfo
{
    const PHYSFS_uint8 *buf;
    PHYSFS_uint64 len;
    PHYSFS_uint64 pos;
    PHYSFS_Io *parent;
    volatile PHYSFS_uint32 refcount;
    void (*destruct)(void *);
} MemoryIoInfo;

static PHYSFS_sint64 memoryIo_read(PHYSFS_Io *io, void *buf, PHYSFS_uint64 len)
{
    MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
    const PHYSFS_uint64 avail = info->len - info->pos;
    assert(avail <= info->len);

    if (avail == 0)
        return 0;  /* we're at EOF; nothing to do. */

    if (len > avail)
        len = avail;

    memcpy(buf, info->buf + info->pos, (size_t) len);
    info->pos += len;
    return len;
} /* memoryIo_read */

static PHYSFS_sint64 memoryIo_write(PHYSFS_Io *io, const void *buffer,
                                    PHYSFS_uint64 len)
{
    BAIL_MACRO(PHYSFS_ERR_OPEN_FOR_READING, -1);
} /* memoryIo_write */

static int memoryIo_seek(PHYSFS_Io *io, PHYSFS_uint64 offset)
{
    MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
    BAIL_IF_MACRO(offset > info->len, PHYSFS_ERR_PAST_EOF, 0);
    info->pos = offset;
    return 1;
} /* memoryIo_seek */

static PHYSFS_sint64 memoryIo_tell(PHYSFS_Io *io)
{
    const MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
    return (PHYSFS_sint64) info->pos;
} /* memoryIo_tell */

static PHYSFS_sint64 memoryIo_length(PHYSFS_Io *io)
{
    const MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
    return (PHYSFS_sint64) info->len;
} /* memoryIo_length */

static PHYSFS_Io *memoryIo_duplicate(PHYSFS_Io *io)
{
    MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
    MemoryIoInfo *newinfo = NULL;
    PHYSFS_Io *parent = info->parent;
    PHYSFS_Io *retval = NULL;

    /* avoid deep copies. */
    assert((!parent) || (!((MemoryIoInfo *) parent->opaque)->parent) );

    /* share the buffer between duplicates. */
    if (parent != NULL)  /* dup the parent, increment its refcount. */
        return parent->duplicate(parent);

    /* we're the parent. */

    retval = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
    BAIL_IF_MACRO(!retval, PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    newinfo = (MemoryIoInfo *) allocator.Malloc(sizeof (MemoryIoInfo));
    if (!newinfo)
    {
        allocator.Free(retval);
        BAIL_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    } /* if */

    /* !!! FIXME: want lockless atomic increment. */
    __PHYSFS_platformGrabMutex(stateLock);
    info->refcount++;
    __PHYSFS_platformReleaseMutex(stateLock);

    memset(newinfo, '\0', sizeof (*info));
    newinfo->buf = info->buf;
    newinfo->len = info->len;
    newinfo->pos = 0;
    newinfo->parent = io;
    newinfo->refcount = 0;
    newinfo->destruct = NULL;

    memcpy(retval, io, sizeof (*retval));
    retval->opaque = newinfo;
    return retval;
} /* memoryIo_duplicate */

static int memoryIo_flush(PHYSFS_Io *io) { return 1;  /* it's read-only. */ }

static void memoryIo_destroy(PHYSFS_Io *io)
{
    MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
    PHYSFS_Io *parent = info->parent;
    int should_die = 0;

    if (parent != NULL)
    {
        assert(info->buf == ((MemoryIoInfo *) info->parent->opaque)->buf);
        assert(info->len == ((MemoryIoInfo *) info->parent->opaque)->len);
        assert(info->refcount == 0);
        assert(info->destruct == NULL);
        allocator.Free(info);
        allocator.Free(io);
        parent->destroy(parent);  /* decrements refcount. */
        return;
    } /* if */

    /* we _are_ the parent. */
    assert(info->refcount > 0);  /* even in a race, we hold a reference. */

    /* !!! FIXME: want lockless atomic decrement. */
    __PHYSFS_platformGrabMutex(stateLock);
    info->refcount--;
    should_die = (info->refcount == 0);
    __PHYSFS_platformReleaseMutex(stateLock);

    if (should_die)
    {
        void (*destruct)(void *) = info->destruct;
        void *buf = (void *) info->buf;
        io->opaque = NULL;  /* kill this here in case of race. */
        allocator.Free(info);
        allocator.Free(io);
        if (destruct != NULL)
            destruct(buf);
    } /* if */
} /* memoryIo_destroy */


static const PHYSFS_Io __PHYSFS_memoryIoInterface =
{
    CURRENT_PHYSFS_IO_API_VERSION, NULL,
    memoryIo_read,
    memoryIo_write,
    memoryIo_seek,
    memoryIo_tell,
    memoryIo_length,
    memoryIo_duplicate,
    memoryIo_flush,
    memoryIo_destroy
};

PHYSFS_Io *__PHYSFS_createMemoryIo(const void *buf, PHYSFS_uint64 len,
                                   void (*destruct)(void *))
{
    PHYSFS_Io *io = NULL;
    MemoryIoInfo *info = NULL;

    io = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
    GOTO_IF_MACRO(!io, PHYSFS_ERR_OUT_OF_MEMORY, createMemoryIo_failed);
    info = (MemoryIoInfo *) allocator.Malloc(sizeof (MemoryIoInfo));
    GOTO_IF_MACRO(!info, PHYSFS_ERR_OUT_OF_MEMORY, createMemoryIo_failed);

    memset(info, '\0', sizeof (*info));
    info->buf = (const PHYSFS_uint8 *) buf;
    info->len = len;
    info->pos = 0;
    info->parent = NULL;
    info->refcount = 1;
    info->destruct = destruct;

    memcpy(io, &__PHYSFS_memoryIoInterface, sizeof (*io));
    io->opaque = info;
    return io;

createMemoryIo_failed:
    if (info != NULL) allocator.Free(info);
    if (io != NULL) allocator.Free(io);
    return NULL;
} /* __PHYSFS_createMemoryIo */


/* PHYSFS_Io implementation for i/o to a PHYSFS_File... */

static PHYSFS_sint64 handleIo_read(PHYSFS_Io *io, void *buf, PHYSFS_uint64 len)
{
    return PHYSFS_readBytes((PHYSFS_File *) io->opaque, buf, len);
} /* handleIo_read */

static PHYSFS_sint64 handleIo_write(PHYSFS_Io *io, const void *buffer,
                                    PHYSFS_uint64 len)
{
    return PHYSFS_writeBytes((PHYSFS_File *) io->opaque, buffer, len);
} /* handleIo_write */

static int handleIo_seek(PHYSFS_Io *io, PHYSFS_uint64 offset)
{
    return PHYSFS_seek((PHYSFS_File *) io->opaque, offset);
} /* handleIo_seek */

static PHYSFS_sint64 handleIo_tell(PHYSFS_Io *io)
{
    return PHYSFS_tell((PHYSFS_File *) io->opaque);
} /* handleIo_tell */

static PHYSFS_sint64 handleIo_length(PHYSFS_Io *io)
{
    return PHYSFS_fileLength((PHYSFS_File *) io->opaque);
} /* handleIo_length */

static PHYSFS_Io *handleIo_duplicate(PHYSFS_Io *io)
{
    /*
     * There's no duplicate at the PHYSFS_File level, so we break the
     *  abstraction. We're allowed to: we're physfs.c!
     */
    FileHandle *origfh = (FileHandle *) io->opaque;
    FileHandle *newfh = (FileHandle *) allocator.Malloc(sizeof (FileHandle));
    PHYSFS_Io *retval = NULL;

    GOTO_IF_MACRO(!newfh, PHYSFS_ERR_OUT_OF_MEMORY, handleIo_dupe_failed);
    memset(newfh, '\0', sizeof (*newfh));

    retval = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
    GOTO_IF_MACRO(!retval, PHYSFS_ERR_OUT_OF_MEMORY, handleIo_dupe_failed);

#if 0  /* we don't buffer the duplicate, at least not at the moment. */
    if (origfh->buffer != NULL)
    {
        newfh->buffer = (PHYSFS_uint8 *) allocator.Malloc(origfh->bufsize);
        if (!newfh->buffer)
            GOTO_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, handleIo_dupe_failed);
        newfh->bufsize = origfh->bufsize;
    } /* if */
#endif

    newfh->io = origfh->io->duplicate(origfh->io);
    GOTO_IF_MACRO(!newfh->io, ERRPASS, handleIo_dupe_failed);

    newfh->forReading = origfh->forReading;
    newfh->dirHandle = origfh->dirHandle;

    __PHYSFS_platformGrabMutex(stateLock);
    if (newfh->forReading)
    {
        newfh->next = openReadList;
        openReadList = newfh;
    } /* if */
    else
    {
        newfh->next = openWriteList;
        openWriteList = newfh;
    } /* else */
    __PHYSFS_platformReleaseMutex(stateLock);

    memcpy(retval, io, sizeof (PHYSFS_Io));
    retval->opaque = newfh;
    return retval;
    
handleIo_dupe_failed:
    if (newfh)
    {
        if (newfh->io != NULL) newfh->io->destroy(newfh->io);
        if (newfh->buffer != NULL) allocator.Free(newfh->buffer);
        allocator.Free(newfh);
    } /* if */

    return NULL;
} /* handleIo_duplicate */

static int handleIo_flush(PHYSFS_Io *io)
{
    return PHYSFS_flush((PHYSFS_File *) io->opaque);
} /* handleIo_flush */

static void handleIo_destroy(PHYSFS_Io *io)
{
    if (io->opaque != NULL)
        PHYSFS_close((PHYSFS_File *) io->opaque);
    allocator.Free(io);
} /* handleIo_destroy */

static const PHYSFS_Io __PHYSFS_handleIoInterface =
{
    CURRENT_PHYSFS_IO_API_VERSION, NULL,
    handleIo_read,
    handleIo_write,
    handleIo_seek,
    handleIo_tell,
    handleIo_length,
    handleIo_duplicate,
    handleIo_flush,
    handleIo_destroy
};

static PHYSFS_Io *__PHYSFS_createHandleIo(PHYSFS_File *f)
{
    PHYSFS_Io *io = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
    BAIL_IF_MACRO(!io, PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    memcpy(io, &__PHYSFS_handleIoInterface, sizeof (*io));
    io->opaque = f;
    return io;
} /* __PHYSFS_createHandleIo */


/* functions ... */

typedef struct
{
    char **list;
    PHYSFS_uint32 size;
    PHYSFS_ErrorCode errcode;
} EnumStringListCallbackData;

static void enumStringListCallback(void *data, const char *str)
{
    void *ptr;
    char *newstr;
    EnumStringListCallbackData *pecd = (EnumStringListCallbackData *) data;

    if (pecd->errcode)
        return;

    ptr = allocator.Realloc(pecd->list, (pecd->size + 2) * sizeof (char *));
    newstr = (char *) allocator.Malloc(strlen(str) + 1);
    if (ptr != NULL)
        pecd->list = (char **) ptr;

    if ((ptr == NULL) || (newstr == NULL))
    {
        pecd->errcode = PHYSFS_ERR_OUT_OF_MEMORY;
        pecd->list[pecd->size] = NULL;
        PHYSFS_freeList(pecd->list);
        return;
    } /* if */

    strcpy(newstr, str);
    pecd->list[pecd->size] = newstr;
    pecd->size++;
} /* enumStringListCallback */


static char **doEnumStringList(void (*func)(PHYSFS_StringCallback, void *))
{
    EnumStringListCallbackData ecd;
    memset(&ecd, '\0', sizeof (ecd));
    ecd.list = (char **) allocator.Malloc(sizeof (char *));
    BAIL_IF_MACRO(!ecd.list, PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    func(enumStringListCallback, &ecd);

    if (ecd.errcode)
    {
        __PHYSFS_setError(ecd.errcode);
        return NULL;
    } /* if */

    ecd.list[ecd.size] = NULL;
    return ecd.list;
} /* doEnumStringList */


static void __PHYSFS_bubble_sort(void *a, size_t lo, size_t hi,
                                 int (*cmpfn)(void *, size_t, size_t),
                                 void (*swapfn)(void *, size_t, size_t))
{
    size_t i;
    int sorted;

    do
    {
        sorted = 1;
        for (i = lo; i < hi; i++)
        {
            if (cmpfn(a, i, i + 1) > 0)
            {
                swapfn(a, i, i + 1);
                sorted = 0;
            } /* if */
        } /* for */
    } while (!sorted);
} /* __PHYSFS_bubble_sort */


static void __PHYSFS_quick_sort(void *a, size_t lo, size_t hi,
                         int (*cmpfn)(void *, size_t, size_t),
                         void (*swapfn)(void *, size_t, size_t))
{
    size_t i;
    size_t j;
    size_t v;

    if ((hi - lo) <= PHYSFS_QUICKSORT_THRESHOLD)
        __PHYSFS_bubble_sort(a, lo, hi, cmpfn, swapfn);
    else
    {
        i = (hi + lo) / 2;

        if (cmpfn(a, lo, i) > 0) swapfn(a, lo, i);
        if (cmpfn(a, lo, hi) > 0) swapfn(a, lo, hi);
        if (cmpfn(a, i, hi) > 0) swapfn(a, i, hi);

        j = hi - 1;
        swapfn(a, i, j);
        i = lo;
        v = j;
        while (1)
        {
            while(cmpfn(a, ++i, v) < 0) { /* do nothing */ }
            while(cmpfn(a, --j, v) > 0) { /* do nothing */ }
            if (j < i)
                break;
            swapfn(a, i, j);
        } /* while */
        if (i != (hi-1))
            swapfn(a, i, hi-1);
        __PHYSFS_quick_sort(a, lo, j, cmpfn, swapfn);
        __PHYSFS_quick_sort(a, i+1, hi, cmpfn, swapfn);
    } /* else */
} /* __PHYSFS_quick_sort */


void __PHYSFS_sort(void *entries, size_t max,
                   int (*cmpfn)(void *, size_t, size_t),
                   void (*swapfn)(void *, size_t, size_t))
{
    /*
     * Quicksort w/ Bubblesort fallback algorithm inspired by code from here:
     *   http://www.cs.ubc.ca/spider/harrison/Java/sorting-demo.html
     */
    if (max > 0)
        __PHYSFS_quick_sort(entries, 0, max - 1, cmpfn, swapfn);
} /* __PHYSFS_sort */


static ErrState *findErrorForCurrentThread(void)
{
    ErrState *i;
    void *tid;

    if (errorLock != NULL)
        __PHYSFS_platformGrabMutex(errorLock);

    if (errorStates != NULL)
    {
        tid = __PHYSFS_platformGetThreadID();

        for (i = errorStates; i != NULL; i = i->next)
        {
            if (i->tid == tid)
            {
                if (errorLock != NULL)
                    __PHYSFS_platformReleaseMutex(errorLock);
                return i;
            } /* if */
        } /* for */
    } /* if */

    if (errorLock != NULL)
        __PHYSFS_platformReleaseMutex(errorLock);

    return NULL;   /* no error available. */
} /* findErrorForCurrentThread */


void __PHYSFS_setError(const PHYSFS_ErrorCode errcode)
{
    ErrState *err;

    if (!errcode)
        return;

    err = findErrorForCurrentThread();
    if (err == NULL)
    {
        err = (ErrState *) allocator.Malloc(sizeof (ErrState));
        if (err == NULL)
            return;   /* uhh...? */

        memset(err, '\0', sizeof (ErrState));
        err->tid = __PHYSFS_platformGetThreadID();

        if (errorLock != NULL)
            __PHYSFS_platformGrabMutex(errorLock);

        err->next = errorStates;
        errorStates = err;

        if (errorLock != NULL)
            __PHYSFS_platformReleaseMutex(errorLock);
    } /* if */

    err->code = errcode;
} /* __PHYSFS_setError */


PHYSFS_ErrorCode PHYSFS_getLastErrorCode(void)
{
    ErrState *err = findErrorForCurrentThread();
    const PHYSFS_ErrorCode retval = (err) ? err->code : PHYSFS_ERR_OK;
    if (err)
        err->code = PHYSFS_ERR_OK;
    return retval;
} /* PHYSFS_getLastErrorCode */


PHYSFS_DECL const char *PHYSFS_getErrorByCode(PHYSFS_ErrorCode code)
{
    switch (code)
    {
        case PHYSFS_ERR_OK: return "no error";
        case PHYSFS_ERR_OTHER_ERROR: return "unknown error";
        case PHYSFS_ERR_OUT_OF_MEMORY: return "out of memory";
        case PHYSFS_ERR_NOT_INITIALIZED: return "not initialized";
        case PHYSFS_ERR_IS_INITIALIZED: return "already initialized";
        case PHYSFS_ERR_ARGV0_IS_NULL: return "argv[0] is NULL";
        case PHYSFS_ERR_UNSUPPORTED: return "unsupported";
        case PHYSFS_ERR_PAST_EOF: return "past end of file";
        case PHYSFS_ERR_FILES_STILL_OPEN: return "files still open";
        case PHYSFS_ERR_INVALID_ARGUMENT: return "invalid argument";
        case PHYSFS_ERR_NOT_MOUNTED: return "not mounted";
        case PHYSFS_ERR_NOT_FOUND: return "not found";
        case PHYSFS_ERR_SYMLINK_FORBIDDEN: return "symlinks are forbidden";
        case PHYSFS_ERR_NO_WRITE_DIR: return "write directory is not set";
        case PHYSFS_ERR_OPEN_FOR_READING: return "file open for reading";
        case PHYSFS_ERR_OPEN_FOR_WRITING: return "file open for writing";
        case PHYSFS_ERR_NOT_A_FILE: return "not a file";
        case PHYSFS_ERR_READ_ONLY: return "read-only filesystem";
        case PHYSFS_ERR_CORRUPT: return "corrupted";
        case PHYSFS_ERR_SYMLINK_LOOP: return "infinite symbolic link loop";
        case PHYSFS_ERR_IO: return "i/o error";
        case PHYSFS_ERR_PERMISSION: return "permission denied";
        case PHYSFS_ERR_NO_SPACE: return "no space available for writing";
        case PHYSFS_ERR_BAD_FILENAME: return "filename is illegal or insecure";
        case PHYSFS_ERR_BUSY: return "tried to modify a file the OS needs";
        case PHYSFS_ERR_DIR_NOT_EMPTY: return "directory isn't empty";
        case PHYSFS_ERR_OS_ERROR: return "OS reported an error";
        case PHYSFS_ERR_DUPLICATE: return "duplicate resource";
    } /* switch */

    return NULL;  /* don't know this error code. */
} /* PHYSFS_getErrorByCode */


void PHYSFS_setErrorCode(PHYSFS_ErrorCode code)
{
    __PHYSFS_setError(code);
} /* PHYSFS_setErrorCode */


const char *PHYSFS_getLastError(void)
{
    const PHYSFS_ErrorCode err = PHYSFS_getLastErrorCode();
    return (err) ? PHYSFS_getErrorByCode(err) : NULL;
} /* PHYSFS_getLastError */


/* MAKE SURE that errorLock is held before calling this! */
static void freeErrorStates(void)
{
    ErrState *i;
    ErrState *next;

    for (i = errorStates; i != NULL; i = next)
    {
        next = i->next;
        allocator.Free(i);
    } /* for */

    errorStates = NULL;
} /* freeErrorStates */


void PHYSFS_getLinkedVersion(PHYSFS_Version *ver)
{
    if (ver != NULL)
    {
        ver->major = PHYSFS_VER_MAJOR;
        ver->minor = PHYSFS_VER_MINOR;
        ver->patch = PHYSFS_VER_PATCH;
    } /* if */
} /* PHYSFS_getLinkedVersion */


static const char *find_filename_extension(const char *fname)
{
    const char *retval = NULL;
    if (fname != NULL)
    {
        const char *p = strchr(fname, '.');
        retval = p;

        while (p != NULL)
        {
            p = strchr(p + 1, '.');
            if (p != NULL)
                retval = p;
        } /* while */

        if (retval != NULL)
            retval++;  /* skip '.' */
    } /* if */

    return retval;
} /* find_filename_extension */


static DirHandle *tryOpenDir(PHYSFS_Io *io, const PHYSFS_Archiver *funcs,
                             const char *d, int forWriting)
{
    DirHandle *retval = NULL;
    void *opaque = NULL;

    if (io != NULL)
        BAIL_IF_MACRO(!io->seek(io, 0), ERRPASS, NULL);

    opaque = funcs->openArchive(io, d, forWriting);
    if (opaque != NULL)
    {
        retval = (DirHandle *) allocator.Malloc(sizeof (DirHandle));
        if (retval == NULL)
            funcs->closeArchive(opaque);
        else
        {
            memset(retval, '\0', sizeof (DirHandle));
            retval->mountPoint = NULL;
            retval->funcs = funcs;
            retval->opaque = opaque;
        } /* else */
    } /* if */

    return retval;
} /* tryOpenDir */


static DirHandle *openDirectory(PHYSFS_Io *io, const char *d, int forWriting)
{
    DirHandle *retval = NULL;
    const PHYSFS_Archiver **i;
    const char *ext;

    assert((io != NULL) || (d != NULL));

    if (io == NULL)
    {
        /* DIR gets first shot (unlike the rest, it doesn't deal with files). */
        retval = tryOpenDir(io, &__PHYSFS_Archiver_DIR, d, forWriting);
        if (retval != NULL)
            return retval;

        io = __PHYSFS_createNativeIo(d, forWriting ? 'w' : 'r');
        BAIL_IF_MACRO(!io, ERRPASS, 0);
    } /* if */

    ext = find_filename_extension(d);
    if (ext != NULL)
    {
        /* Look for archivers with matching file extensions first... */
        for (i = archivers; (*i != NULL) && (retval == NULL); i++)
        {
            if (__PHYSFS_utf8stricmp(ext, (*i)->info.extension) == 0)
                retval = tryOpenDir(io, *i, d, forWriting);
        } /* for */

        /* failing an exact file extension match, try all the others... */
        for (i = archivers; (*i != NULL) && (retval == NULL); i++)
        {
            if (__PHYSFS_utf8stricmp(ext, (*i)->info.extension) != 0)
                retval = tryOpenDir(io, *i, d, forWriting);
        } /* for */
    } /* if */

    else  /* no extension? Try them all. */
    {
        for (i = archivers; (*i != NULL) && (retval == NULL); i++)
            retval = tryOpenDir(io, *i, d, forWriting);
    } /* else */

    BAIL_IF_MACRO(!retval, PHYSFS_ERR_UNSUPPORTED, NULL);
    return retval;
} /* openDirectory */


/*
 * Make a platform-independent path string sane. Doesn't actually check the
 *  file hierarchy, it just cleans up the string.
 *  (dst) must be a buffer at least as big as (src), as this is where the
 *  cleaned up string is deposited.
 * If there are illegal bits in the path (".." entries, etc) then we
 *  return zero and (dst) is undefined. Non-zero if the path was sanitized.
 */
static int sanitizePlatformIndependentPath(const char *src, char *dst)
{
    char *prev;
    char ch;

    while (*src == '/')  /* skip initial '/' chars... */
        src++;

    prev = dst;
    do
    {
        ch = *(src++);

        if ((ch == ':') || (ch == '\\'))  /* illegal chars in a physfs path. */
            BAIL_MACRO(PHYSFS_ERR_BAD_FILENAME, 0);

        if (ch == '/')   /* path separator. */
        {
            *dst = '\0';  /* "." and ".." are illegal pathnames. */
            if ((strcmp(prev, ".") == 0) || (strcmp(prev, "..") == 0))
                BAIL_MACRO(PHYSFS_ERR_BAD_FILENAME, 0);

            while (*src == '/')   /* chop out doubles... */
                src++;

            if (*src == '\0') /* ends with a pathsep? */
                break;  /* we're done, don't add final pathsep to dst. */

            prev = dst + 1;
        } /* if */

        *(dst++) = ch;
    } while (ch != '\0');

    return 1;
} /* sanitizePlatformIndependentPath */


/*
 * Figure out if (fname) is part of (h)'s mountpoint. (fname) must be an
 *  output from sanitizePlatformIndependentPath(), so that it is in a known
 *  state.
 *
 * This only finds legitimate segments of a mountpoint. If the mountpoint is
 *  "/a/b/c" and (fname) is "/a/b/c", "/", or "/a/b/c/d", then the results are
 *  all zero. "/a/b" will succeed, though.
 */
static int partOfMountPoint(DirHandle *h, char *fname)
{
    /* !!! FIXME: This code feels gross. */
    int rc;
    size_t len, mntpntlen;

    if (h->mountPoint == NULL)
        return 0;
    else if (*fname == '\0')
        return 1;

    len = strlen(fname);
    mntpntlen = strlen(h->mountPoint);
    if (len > mntpntlen)  /* can't be a subset of mountpoint. */
        return 0;

    /* if true, must be not a match or a complete match, but not a subset. */
    if ((len + 1) == mntpntlen)
        return 0;

    rc = strncmp(fname, h->mountPoint, len); /* !!! FIXME: case insensitive? */
    if (rc != 0)
        return 0;  /* not a match. */

    /* make sure /a/b matches /a/b/ and not /a/bc ... */
    return h->mountPoint[len] == '/';
} /* partOfMountPoint */


static DirHandle *createDirHandle(PHYSFS_Io *io, const char *newDir,
                                  const char *mountPoint, int forWriting)
{
    DirHandle *dirHandle = NULL;
    char *tmpmntpnt = NULL;

    if (mountPoint != NULL)
    {
        const size_t len = strlen(mountPoint) + 1;
        tmpmntpnt = (char *) __PHYSFS_smallAlloc(len);
        GOTO_IF_MACRO(!tmpmntpnt, PHYSFS_ERR_OUT_OF_MEMORY, badDirHandle);
        if (!sanitizePlatformIndependentPath(mountPoint, tmpmntpnt))
            goto badDirHandle;
        mountPoint = tmpmntpnt;  /* sanitized version. */
    } /* if */

    dirHandle = openDirectory(io, newDir, forWriting);
    GOTO_IF_MACRO(!dirHandle, ERRPASS, badDirHandle);

    if (newDir == NULL)
        dirHandle->dirName = NULL;
    else
    {
        dirHandle->dirName = (char *) allocator.Malloc(strlen(newDir) + 1);
        if (!dirHandle->dirName)
            GOTO_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, badDirHandle);
        strcpy(dirHandle->dirName, newDir);
    } /* else */

    if ((mountPoint != NULL) && (*mountPoint != '\0'))
    {
        dirHandle->mountPoint = (char *)allocator.Malloc(strlen(mountPoint)+2);
        if (!dirHandle->mountPoint)
            GOTO_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, badDirHandle);
        strcpy(dirHandle->mountPoint, mountPoint);
        strcat(dirHandle->mountPoint, "/");
    } /* if */

    __PHYSFS_smallFree(tmpmntpnt);
    return dirHandle;

badDirHandle:
    if (dirHandle != NULL)
    {
        dirHandle->funcs->closeArchive(dirHandle->opaque);
        allocator.Free(dirHandle->dirName);
        allocator.Free(dirHandle->mountPoint);
        allocator.Free(dirHandle);
    } /* if */

    __PHYSFS_smallFree(tmpmntpnt);
    return NULL;
} /* createDirHandle */


/* MAKE SURE you've got the stateLock held before calling this! */
static int freeDirHandle(DirHandle *dh, FileHandle *openList)
{
    FileHandle *i;

    if (dh == NULL)
        return 1;

    for (i = openList; i != NULL; i = i->next)
        BAIL_IF_MACRO(i->dirHandle == dh, PHYSFS_ERR_FILES_STILL_OPEN, 0);

    dh->funcs->closeArchive(dh->opaque);
    allocator.Free(dh->dirName);
    allocator.Free(dh->mountPoint);
    allocator.Free(dh);
    return 1;
} /* freeDirHandle */


static char *calculateBaseDir(const char *argv0)
{
    const char dirsep = __PHYSFS_platformDirSeparator;
    char *retval = NULL;
    char *ptr = NULL;

    /* Give the platform layer first shot at this. */
    retval = __PHYSFS_platformCalcBaseDir(argv0);
    if (retval != NULL)
        return retval;

    /* We need argv0 to go on. */
    BAIL_IF_MACRO(argv0 == NULL, PHYSFS_ERR_ARGV0_IS_NULL, NULL);

    ptr = strrchr(argv0, dirsep);
    if (ptr != NULL)
    {
        const size_t size = ((size_t) (ptr - argv0)) + 1;
        retval = (char *) allocator.Malloc(size + 1);
        BAIL_IF_MACRO(!retval, PHYSFS_ERR_OUT_OF_MEMORY, NULL);
        memcpy(retval, argv0, size);
        retval[size] = '\0';
        return retval;
    } /* if */

    /* argv0 wasn't helpful. */
    BAIL_MACRO(PHYSFS_ERR_INVALID_ARGUMENT, NULL);
} /* calculateBaseDir */


static int initializeMutexes(void)
{
    errorLock = __PHYSFS_platformCreateMutex();
    if (errorLock == NULL)
        goto initializeMutexes_failed;

    stateLock = __PHYSFS_platformCreateMutex();
    if (stateLock == NULL)
        goto initializeMutexes_failed;

    return 1;  /* success. */

initializeMutexes_failed:
    if (errorLock != NULL)
        __PHYSFS_platformDestroyMutex(errorLock);

    if (stateLock != NULL)
        __PHYSFS_platformDestroyMutex(stateLock);

    errorLock = stateLock = NULL;
    return 0;  /* failed. */
} /* initializeMutexes */


static int doRegisterArchiver(const PHYSFS_Archiver *_archiver);

static int initStaticArchivers(void)
{
    const PHYSFS_Archiver * const *i;

    assert(__PHYSFS_ARRAYLEN(staticArchivers) > 0);  /* at least a NULL. */
    assert(staticArchivers[__PHYSFS_ARRAYLEN(staticArchivers) - 1] == NULL);

    for (i = staticArchivers; *i != NULL; i++)
    {
        if (!doRegisterArchiver(*i))
            return 0;
    } /* for */

    return 1;
} /* initStaticArchivers */


static void setDefaultAllocator(void);
static int doDeinit(void);

int PHYSFS_init(const char *argv0)
{
    BAIL_IF_MACRO(initialized, PHYSFS_ERR_IS_INITIALIZED, 0);

    if (!externalAllocator)
        setDefaultAllocator();

    if ((allocator.Init != NULL) && (!allocator.Init())) return 0;

    if (!__PHYSFS_platformInit())
    {
        if (allocator.Deinit != NULL) allocator.Deinit();
        return 0;
    } /* if */

    /* everything below here can be cleaned up safely by doDeinit(). */

    if (!initializeMutexes()) goto initFailed;

    baseDir = calculateBaseDir(argv0);
    if (!baseDir) goto initFailed;

    userDir = __PHYSFS_platformCalcUserDir();
    if (!userDir) goto initFailed;

    /* Platform layer is required to append a dirsep. */
    assert(baseDir[strlen(baseDir) - 1] == __PHYSFS_platformDirSeparator);
    assert(userDir[strlen(userDir) - 1] == __PHYSFS_platformDirSeparator);

    if (!initStaticArchivers()) goto initFailed;

    initialized = 1;

    /* This makes sure that the error subsystem is initialized. */
    __PHYSFS_setError(PHYSFS_getLastErrorCode());

    return 1;

initFailed:
    doDeinit();
    return 0;
} /* PHYSFS_init */


/* MAKE SURE you hold stateLock before calling this! */
static int closeFileHandleList(FileHandle **list)
{
    FileHandle *i;
    FileHandle *next = NULL;

    for (i = *list; i != NULL; i = next)
    {
        PHYSFS_Io *io = i->io;
        next = i->next;

        if (!io->flush(io))
        {
            *list = i;
            return 0;
        } /* if */

        io->destroy(io);
        allocator.Free(i);
    } /* for */

    *list = NULL;
    return 1;
} /* closeFileHandleList */


/* MAKE SURE you hold the stateLock before calling this! */
static void freeSearchPath(void)
{
    DirHandle *i;
    DirHandle *next = NULL;

    closeFileHandleList(&openReadList);

    if (searchPath != NULL)
    {
        for (i = searchPath; i != NULL; i = next)
        {
            next = i->next;
            freeDirHandle(i, openReadList);
        } /* for */
        searchPath = NULL;
    } /* if */
} /* freeSearchPath */


/* MAKE SURE you hold stateLock before calling this! */
static int archiverInUse(const PHYSFS_Archiver *arc, const DirHandle *list)
{
    const DirHandle *i;
    for (i = list; i != NULL; i = i->next)
    {
        if (i->funcs == arc)
            return 1;
    } /* for */

    return 0;  /* not in use */
} /* archiverInUse */


/* MAKE SURE you hold stateLock before calling this! */
static int doDeregisterArchiver(const size_t idx)
{
    const size_t len = (numArchivers - idx) * sizeof (void *);
    const PHYSFS_ArchiveInfo *info = archiveInfo[idx];
    const PHYSFS_Archiver *arc = archivers[idx];

    /* make sure nothing is still using this archiver */
    if (archiverInUse(arc, searchPath) || archiverInUse(arc, writeDir))
        BAIL_MACRO(PHYSFS_ERR_FILES_STILL_OPEN, 0);

    allocator.Free((void *) info->extension);
    allocator.Free((void *) info->description);
    allocator.Free((void *) info->author);
    allocator.Free((void *) info->url);
    allocator.Free((void *) arc);

    memmove(&archiveInfo[idx], &archiveInfo[idx+1], len);
    memmove(&archivers[idx], &archivers[idx+1], len);

    assert(numArchivers > 0);
    numArchivers--;

    return 1;
} /* doDeregisterArchiver */


/* Does NOT hold the state lock; we're shutting down. */
static void freeArchivers(void)
{
    while (numArchivers > 0)
    {
        const int rc = doDeregisterArchiver(numArchivers - 1);
        assert(rc);  /* nothing should be mounted during shutdown. */
    } /* while */

    allocator.Free(archivers);
    allocator.Free(archiveInfo);
    archivers = NULL;
    archiveInfo = NULL;
} /* freeArchivers */


static int doDeinit(void)
{
    BAIL_IF_MACRO(!__PHYSFS_platformDeinit(), ERRPASS, 0);

    closeFileHandleList(&openWriteList);
    BAIL_IF_MACRO(!PHYSFS_setWriteDir(NULL), PHYSFS_ERR_FILES_STILL_OPEN, 0);

    freeSearchPath();
    freeArchivers();
    freeErrorStates();

    if (baseDir != NULL)
    {
        allocator.Free(baseDir);
        baseDir = NULL;
    } /* if */

    if (userDir != NULL)
    {
        allocator.Free(userDir);
        userDir = NULL;
    } /* if */

    if (prefDir != NULL)
    {
        allocator.Free(prefDir);
        prefDir = NULL;
    } /* if */

    if (archiveInfo != NULL)
    {
        allocator.Free(archiveInfo);
        archiveInfo = NULL;
    } /* if */

    if (archivers != NULL)
    {
        allocator.Free(archivers);
        archivers = NULL;
    } /* if */

    allowSymLinks = 0;
    initialized = 0;

    if (errorLock) __PHYSFS_platformDestroyMutex(errorLock);
    if (stateLock) __PHYSFS_platformDestroyMutex(stateLock);

    if (allocator.Deinit != NULL)
        allocator.Deinit();

    errorLock = stateLock = NULL;
    return 1;
} /* doDeinit */


int PHYSFS_deinit(void)
{
    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, 0);
    return doDeinit();
} /* PHYSFS_deinit */


int PHYSFS_isInit(void)
{
    return initialized;
} /* PHYSFS_isInit */


static char *PHYSFS_strdup(const char *str)
{
    char *retval = (char *) allocator.Malloc(strlen(str) + 1);
    if (retval)
        strcpy(retval, str);
    return retval;
} /* PHYSFS_strdup */


/* MAKE SURE you hold stateLock before calling this! */
static int doRegisterArchiver(const PHYSFS_Archiver *_archiver)
{
    const PHYSFS_uint32 maxver = CURRENT_PHYSFS_ARCHIVER_API_VERSION;
    const size_t len = (numArchivers + 2) * sizeof (void *);
    PHYSFS_Archiver *archiver = NULL;
    PHYSFS_ArchiveInfo *info = NULL;
    const char *ext = NULL;
    void *ptr = NULL;
    size_t i;

    BAIL_IF_MACRO(!_archiver, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(_archiver->version > maxver, PHYSFS_ERR_UNSUPPORTED, 0);
    BAIL_IF_MACRO(!_archiver->info.extension, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->info.description, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->info.author, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->info.url, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->openArchive, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->enumerateFiles, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->openRead, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->openWrite, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->openAppend, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->remove, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->mkdir, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->closeArchive, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(!_archiver->stat, PHYSFS_ERR_INVALID_ARGUMENT, 0);

    ext = _archiver->info.extension;
    for (i = 0; i < numArchivers; i++)
    {
        if (__PHYSFS_utf8stricmp(archiveInfo[i]->extension, ext) == 0)
            BAIL_MACRO(PHYSFS_ERR_DUPLICATE, 0);  // !!! FIXME: better error? ERR_IN_USE?
    } /* for */

    /* make a copy of the data. */
    archiver = (PHYSFS_Archiver *) allocator.Malloc(sizeof (*archiver));
    GOTO_IF_MACRO(!archiver, PHYSFS_ERR_OUT_OF_MEMORY, regfailed);

    /* Must copy sizeof (OLD_VERSION_OF_STRUCT) when version changes! */
    memcpy(archiver, _archiver, sizeof (*archiver));

    info = (PHYSFS_ArchiveInfo *) &archiver->info;
    memset(info, '\0', sizeof (*info));  /* NULL in case an alloc fails. */
    #define CPYSTR(item) \
        info->item = PHYSFS_strdup(_archiver->info.item); \
        GOTO_IF_MACRO(!info->item, PHYSFS_ERR_OUT_OF_MEMORY, regfailed);
    CPYSTR(extension);
    CPYSTR(description);
    CPYSTR(author);
    CPYSTR(url);
    info->supportsSymlinks = _archiver->info.supportsSymlinks;
    #undef CPYSTR

    ptr = allocator.Realloc(archiveInfo, len);
    GOTO_IF_MACRO(!ptr, PHYSFS_ERR_OUT_OF_MEMORY, regfailed);
    archiveInfo = (const PHYSFS_ArchiveInfo **) ptr;

    ptr = allocator.Realloc(archivers, len);
    GOTO_IF_MACRO(!ptr, PHYSFS_ERR_OUT_OF_MEMORY, regfailed);
    archivers = (const PHYSFS_Archiver **) ptr;

    archiveInfo[numArchivers] = info;
    archiveInfo[numArchivers + 1] = NULL;

    archivers[numArchivers] = archiver;
    archivers[numArchivers + 1] = NULL;

    numArchivers++;

    return 1;

regfailed:
    if (info != NULL)
    {
        allocator.Free((void *) info->extension);
        allocator.Free((void *) info->description);
        allocator.Free((void *) info->author);
        allocator.Free((void *) info->url);
    } /* if */
    allocator.Free(archiver);

    return 0;
} /* doRegisterArchiver */


int PHYSFS_registerArchiver(const PHYSFS_Archiver *archiver)
{
    int retval;
    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, 0);
    __PHYSFS_platformGrabMutex(stateLock);
    retval = doRegisterArchiver(archiver);
    __PHYSFS_platformReleaseMutex(stateLock);
    return retval;
} /* PHYSFS_registerArchiver */


int PHYSFS_deregisterArchiver(const char *ext)
{
    size_t i;

    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, 0);
    BAIL_IF_MACRO(!ext, PHYSFS_ERR_INVALID_ARGUMENT, 0);

    __PHYSFS_platformGrabMutex(stateLock);
    for (i = 0; i < numArchivers; i++)
    {
        if (__PHYSFS_utf8stricmp(archiveInfo[i]->extension, ext) == 0)
        {
            const int retval = doDeregisterArchiver(i);
            __PHYSFS_platformReleaseMutex(stateLock);
            return retval;
        } /* if */
    } /* for */
    __PHYSFS_platformReleaseMutex(stateLock);

    BAIL_MACRO(PHYSFS_ERR_NOT_FOUND, 0);
} /* PHYSFS_deregisterArchiver */


const PHYSFS_ArchiveInfo **PHYSFS_supportedArchiveTypes(void)
{
    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, NULL);
    return archiveInfo;
} /* PHYSFS_supportedArchiveTypes */


void PHYSFS_freeList(void *list)
{
    void **i;
    if (list != NULL)
    {
        for (i = (void **) list; *i != NULL; i++)
            allocator.Free(*i);

        allocator.Free(list);
    } /* if */
} /* PHYSFS_freeList */


const char *PHYSFS_getDirSeparator(void)
{
    static char retval[2] = { __PHYSFS_platformDirSeparator, '\0' };
    return retval;
} /* PHYSFS_getDirSeparator */


char **PHYSFS_getCdRomDirs(void)
{
    return doEnumStringList(__PHYSFS_platformDetectAvailableCDs);
} /* PHYSFS_getCdRomDirs */


void PHYSFS_getCdRomDirsCallback(PHYSFS_StringCallback callback, void *data)
{
    __PHYSFS_platformDetectAvailableCDs(callback, data);
} /* PHYSFS_getCdRomDirsCallback */


const char *PHYSFS_getPrefDir(const char *org, const char *app)
{
    const char dirsep = __PHYSFS_platformDirSeparator;
    PHYSFS_Stat statbuf;
    char *ptr = NULL;
    char *endstr = NULL;
    int exists = 0;

    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, 0);
    BAIL_IF_MACRO(!org, PHYSFS_ERR_INVALID_ARGUMENT, NULL);
    BAIL_IF_MACRO(*org == '\0', PHYSFS_ERR_INVALID_ARGUMENT, NULL);
    BAIL_IF_MACRO(!app, PHYSFS_ERR_INVALID_ARGUMENT, NULL);
    BAIL_IF_MACRO(*app == '\0', PHYSFS_ERR_INVALID_ARGUMENT, NULL);

    allocator.Free(prefDir);
    prefDir = __PHYSFS_platformCalcPrefDir(org, app);
    BAIL_IF_MACRO(!prefDir, ERRPASS, NULL);

    assert(strlen(prefDir) > 0);
    endstr = prefDir + (strlen(prefDir) - 1);
    assert(*endstr == dirsep);
    *endstr = '\0';  /* mask out the final dirsep for now. */

    if (!__PHYSFS_platformStat(prefDir, &exists, &statbuf))
    {
        for (ptr = strchr(prefDir, dirsep); ptr; ptr = strchr(ptr+1, dirsep))
        {
            *ptr = '\0';
            __PHYSFS_platformMkDir(prefDir);
            *ptr = dirsep;
        } /* for */

        if (!__PHYSFS_platformMkDir(prefDir))
        {
            allocator.Free(prefDir);
            prefDir = NULL;
        } /* if */
    } /* if */

    *endstr = dirsep;  /* readd the final dirsep. */

    return prefDir;
} /* PHYSFS_getPrefDir */


const char *PHYSFS_getBaseDir(void)
{
    return baseDir;   /* this is calculated in PHYSFS_init()... */
} /* PHYSFS_getBaseDir */


const char *__PHYSFS_getUserDir(void)  /* not deprecated internal version. */
{
    return userDir;   /* this is calculated in PHYSFS_init()... */
} /* __PHYSFS_getUserDir */


const char *PHYSFS_getUserDir(void)
{
    return __PHYSFS_getUserDir();
} /* PHYSFS_getUserDir */


const char *PHYSFS_getWriteDir(void)
{
    const char *retval = NULL;

    __PHYSFS_platformGrabMutex(stateLock);
    if (writeDir != NULL)
        retval = writeDir->dirName;
    __PHYSFS_platformReleaseMutex(stateLock);

    return retval;
} /* PHYSFS_getWriteDir */


int PHYSFS_setWriteDir(const char *newDir)
{
    int retval = 1;

    __PHYSFS_platformGrabMutex(stateLock);

    if (writeDir != NULL)
    {
        BAIL_IF_MACRO_MUTEX(!freeDirHandle(writeDir, openWriteList), ERRPASS,
                            stateLock, 0);
        writeDir = NULL;
    } /* if */

    if (newDir != NULL)
    {
        /* !!! FIXME: PHYSFS_Io shouldn't be NULL */
        writeDir = createDirHandle(NULL, newDir, NULL, 1);
        retval = (writeDir != NULL);
    } /* if */

    __PHYSFS_platformReleaseMutex(stateLock);

    return retval;
} /* PHYSFS_setWriteDir */


static int doMount(PHYSFS_Io *io, const char *fname,
                   const char *mountPoint, int appendToPath)
{
    DirHandle *dh;
    DirHandle *prev = NULL;
    DirHandle *i;

    if (mountPoint == NULL)
        mountPoint = "/";

    __PHYSFS_platformGrabMutex(stateLock);

    if (fname != NULL)
    {
        for (i = searchPath; i != NULL; i = i->next)
        {
            /* already in search path? */
            if ((i->dirName != NULL) && (strcmp(fname, i->dirName) == 0))
                BAIL_MACRO_MUTEX(ERRPASS, stateLock, 1);
            prev = i;
        } /* for */
    } /* if */

    dh = createDirHandle(io, fname, mountPoint, 0);
    BAIL_IF_MACRO_MUTEX(!dh, ERRPASS, stateLock, 0);

    if (appendToPath)
    {
        if (prev == NULL)
            searchPath = dh;
        else
            prev->next = dh;
    } /* if */
    else
    {
        dh->next = searchPath;
        searchPath = dh;
    } /* else */

    __PHYSFS_platformReleaseMutex(stateLock);
    return 1;
} /* doMount */


int PHYSFS_mountIo(PHYSFS_Io *io, const char *fname,
                   const char *mountPoint, int appendToPath)
{
    BAIL_IF_MACRO(!io, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    BAIL_IF_MACRO(io->version != 0, PHYSFS_ERR_UNSUPPORTED, 0);
    return doMount(io, fname, mountPoint, appendToPath);
} /* PHYSFS_mountIo */


int PHYSFS_mountMemory(const void *buf, PHYSFS_uint64 len, void (*del)(void *),
                       const char *fname, const char *mountPoint,
                       int appendToPath)
{
    int retval = 0;
    PHYSFS_Io *io = NULL;

    BAIL_IF_MACRO(!buf, PHYSFS_ERR_INVALID_ARGUMENT, 0);

    io = __PHYSFS_createMemoryIo(buf, len, del);
    BAIL_IF_MACRO(!io, ERRPASS, 0);
    retval = doMount(io, fname, mountPoint, appendToPath);
    if (!retval)
    {
        /* docs say not to call (del) in case of failure, so cheat. */
        MemoryIoInfo *info = (MemoryIoInfo *) io->opaque;
        info->destruct = NULL;
        io->destroy(io);
    } /* if */

    return retval;
} /* PHYSFS_mountMemory */


int PHYSFS_mountHandle(PHYSFS_File *file, const char *fname,
                       const char *mountPoint, int appendToPath)
{
    int retval = 0;
    PHYSFS_Io *io = NULL;

    BAIL_IF_MACRO(file == NULL, PHYSFS_ERR_INVALID_ARGUMENT, 0);

    io = __PHYSFS_createHandleIo(file);
    BAIL_IF_MACRO(!io, ERRPASS, 0);
    retval = doMount(io, fname, mountPoint, appendToPath);
    if (!retval)
    {
        /* docs say not to destruct in case of failure, so cheat. */
        io->opaque = NULL;
        io->destroy(io);
    } /* if */

    return retval;
} /* PHYSFS_mountHandle */


int PHYSFS_mount(const char *newDir, const char *mountPoint, int appendToPath)
{
    BAIL_IF_MACRO(!newDir, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    return doMount(NULL, newDir, mountPoint, appendToPath);
} /* PHYSFS_mount */


int PHYSFS_addToSearchPath(const char *newDir, int appendToPath)
{
    return doMount(NULL, newDir, NULL, appendToPath);
} /* PHYSFS_addToSearchPath */


int PHYSFS_removeFromSearchPath(const char *oldDir)
{
    return PHYSFS_unmount(oldDir);
} /* PHYSFS_removeFromSearchPath */


int PHYSFS_unmount(const char *oldDir)
{
    DirHandle *i;
    DirHandle *prev = NULL;
    DirHandle *next = NULL;

    BAIL_IF_MACRO(oldDir == NULL, PHYSFS_ERR_INVALID_ARGUMENT, 0);

    __PHYSFS_platformGrabMutex(stateLock);
    for (i = searchPath; i != NULL; i = i->next)
    {
        if (strcmp(i->dirName, oldDir) == 0)
        {
            next = i->next;
            BAIL_IF_MACRO_MUTEX(!freeDirHandle(i, openReadList), ERRPASS,
                                stateLock, 0);

            if (prev == NULL)
                searchPath = next;
            else
                prev->next = next;

            BAIL_MACRO_MUTEX(ERRPASS, stateLock, 1);
        } /* if */
        prev = i;
    } /* for */

    BAIL_MACRO_MUTEX(PHYSFS_ERR_NOT_MOUNTED, stateLock, 0);
} /* PHYSFS_unmount */


char **PHYSFS_getSearchPath(void)
{
    return doEnumStringList(PHYSFS_getSearchPathCallback);
} /* PHYSFS_getSearchPath */


const char *PHYSFS_getMountPoint(const char *dir)
{
    DirHandle *i;
    __PHYSFS_platformGrabMutex(stateLock);
    for (i = searchPath; i != NULL; i = i->next)
    {
        if (strcmp(i->dirName, dir) == 0)
        {
            const char *retval = ((i->mountPoint) ? i->mountPoint : "/");
            __PHYSFS_platformReleaseMutex(stateLock);
            return retval;
        } /* if */
    } /* for */
    __PHYSFS_platformReleaseMutex(stateLock);

    BAIL_MACRO(PHYSFS_ERR_NOT_MOUNTED, NULL);
} /* PHYSFS_getMountPoint */


void PHYSFS_getSearchPathCallback(PHYSFS_StringCallback callback, void *data)
{
    DirHandle *i;

    __PHYSFS_platformGrabMutex(stateLock);

    for (i = searchPath; i != NULL; i = i->next)
        callback(data, i->dirName);

    __PHYSFS_platformReleaseMutex(stateLock);
} /* PHYSFS_getSearchPathCallback */


/* Split out to avoid stack allocation in a loop. */
static void setSaneCfgAddPath(const char *i, const size_t l, const char *dirsep,
                              int archivesFirst)
{
    const char *d = PHYSFS_getRealDir(i);
    const size_t allocsize = strlen(d) + strlen(dirsep) + l + 1;
    char *str = (char *) __PHYSFS_smallAlloc(allocsize);
    if (str != NULL)
    {
        sprintf(str, "%s%s%s", d, dirsep, i);
        PHYSFS_mount(str, NULL, archivesFirst == 0);
        __PHYSFS_smallFree(str);
    } /* if */
} /* setSaneCfgAddPath */


int PHYSFS_setSaneConfig(const char *organization, const char *appName,
                         const char *archiveExt, int includeCdRoms,
                         int archivesFirst)
{
    const char *dirsep = PHYSFS_getDirSeparator();
    const char *basedir;
    const char *prefdir;

    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, 0);

    prefdir = PHYSFS_getPrefDir(organization, appName);
    BAIL_IF_MACRO(!prefdir, ERRPASS, 0);

    basedir = PHYSFS_getBaseDir();
    BAIL_IF_MACRO(!basedir, ERRPASS, 0);

    BAIL_IF_MACRO(!PHYSFS_setWriteDir(prefdir), PHYSFS_ERR_NO_WRITE_DIR, 0);

    /* Put write dir first in search path... */
    PHYSFS_mount(prefdir, NULL, 0);

    /* Put base path on search path... */
    PHYSFS_mount(basedir, NULL, 1);

    /* handle CD-ROMs... */
    if (includeCdRoms)
    {
        char **cds = PHYSFS_getCdRomDirs();
        char **i;
        for (i = cds; *i != NULL; i++)
            PHYSFS_mount(*i, NULL, 1);
        PHYSFS_freeList(cds);
    } /* if */

    /* Root out archives, and add them to search path... */
    if (archiveExt != NULL)
    {
        char **rc = PHYSFS_enumerateFiles("/");
        char **i;
        size_t extlen = strlen(archiveExt);
        char *ext;

        for (i = rc; *i != NULL; i++)
        {
            size_t l = strlen(*i);
            if ((l > extlen) && ((*i)[l - extlen - 1] == '.'))
            {
                ext = (*i) + (l - extlen);
                if (__PHYSFS_utf8stricmp(ext, archiveExt) == 0)
                    setSaneCfgAddPath(*i, l, dirsep, archivesFirst);
            } /* if */
        } /* for */

        PHYSFS_freeList(rc);
    } /* if */

    return 1;
} /* PHYSFS_setSaneConfig */


void PHYSFS_permitSymbolicLinks(int allow)
{
    allowSymLinks = allow;
} /* PHYSFS_permitSymbolicLinks */


int PHYSFS_symbolicLinksPermitted(void)
{
    return allowSymLinks;
} /* PHYSFS_symbolicLinksPermitted */


/*
 * Verify that (fname) (in platform-independent notation), in relation
 *  to (h) is secure. That means that each element of fname is checked
 *  for symlinks (if they aren't permitted). This also allows for quick
 *  rejection of files that exist outside an archive's mountpoint.
 *
 * With some exceptions (like PHYSFS_mkdir(), which builds multiple subdirs
 *  at a time), you should always pass zero for "allowMissing" for efficiency.
 *
 * (fname) must point to an output from sanitizePlatformIndependentPath(),
 *  since it will make sure that path names are in the right format for
 *  passing certain checks. It will also do checks for "insecure" pathnames
 *  like ".." which should be done once instead of once per archive. This also
 *  gives us license to treat (fname) as scratch space in this function.
 *
 * Returns non-zero if string is safe, zero if there's a security issue.
 *  PHYSFS_getLastError() will specify what was wrong. (*fname) will be
 *  updated to point past any mount point elements so it is prepared to
 *  be used with the archiver directly.
 */
static int verifyPath(DirHandle *h, char **_fname, int allowMissing)
{
    char *fname = *_fname;
    int retval = 1;
    char *start;
    char *end;

    if (*fname == '\0')  /* quick rejection. */
        return 1;

    /* !!! FIXME: This codeblock sucks. */
    if (h->mountPoint != NULL)  /* NULL mountpoint means "/". */
    {
        size_t mntpntlen = strlen(h->mountPoint);
        size_t len = strlen(fname);
        assert(mntpntlen > 1); /* root mount points should be NULL. */
        /* not under the mountpoint, so skip this archive. */
        BAIL_IF_MACRO(len < mntpntlen-1, PHYSFS_ERR_NOT_FOUND, 0);
        /* !!! FIXME: Case insensitive? */
        retval = strncmp(h->mountPoint, fname, mntpntlen-1);
        BAIL_IF_MACRO(retval != 0, PHYSFS_ERR_NOT_FOUND, 0);
        if (len > mntpntlen-1)  /* corner case... */
            BAIL_IF_MACRO(fname[mntpntlen-1]!='/', PHYSFS_ERR_NOT_FOUND, 0);
        fname += mntpntlen-1;  /* move to start of actual archive path. */
        if (*fname == '/')
            fname++;
        *_fname = fname;  /* skip mountpoint for later use. */
        retval = 1;  /* may be reset, below. */
    } /* if */

    start = fname;
    if (!allowSymLinks)
    {
        while (1)
        {
            PHYSFS_Stat statbuf;
            int rc = 0;
            end = strchr(start, '/');

            if (end != NULL) *end = '\0';
            rc = h->funcs->stat(h->opaque, fname, &retval, &statbuf);
            if (rc)
                rc = (statbuf.filetype == PHYSFS_FILETYPE_SYMLINK);
            if (end != NULL) *end = '/';

            /* insecure path (has a disallowed symlink in it)? */
            BAIL_IF_MACRO(rc, PHYSFS_ERR_SYMLINK_FORBIDDEN, 0);

            /* break out early if path element is missing. */
            if (!retval)
            {
                /*
                 * We need to clear it if it's the last element of the path,
                 *  since this might be a non-existant file we're opening
                 *  for writing...
                 */
                if ((end == NULL) || (allowMissing))
                    retval = 1;
                break;
            } /* if */

            if (end == NULL)
                break;

            start = end + 1;
        } /* while */
    } /* if */

    return retval;
} /* verifyPath */


static int doMkdir(const char *_dname, char *dname)
{
    DirHandle *h;
    char *start;
    char *end;
    int retval = 0;
    int exists = 1;  /* force existance check on first path element. */

    BAIL_IF_MACRO(!sanitizePlatformIndependentPath(_dname, dname), ERRPASS, 0);

    __PHYSFS_platformGrabMutex(stateLock);
    BAIL_IF_MACRO_MUTEX(!writeDir, PHYSFS_ERR_NO_WRITE_DIR, stateLock, 0);
    h = writeDir;
    BAIL_IF_MACRO_MUTEX(!verifyPath(h, &dname, 1), ERRPASS, stateLock, 0);

    start = dname;
    while (1)
    {
        end = strchr(start, '/');
        if (end != NULL)
            *end = '\0';

        /* only check for existance if all parent dirs existed, too... */
        if (exists)
        {
            PHYSFS_Stat statbuf;
            const int rc = h->funcs->stat(h->opaque, dname, &exists, &statbuf);
            retval = ((rc) && (statbuf.filetype == PHYSFS_FILETYPE_DIRECTORY));
        } /* if */

        if (!exists)
            retval = h->funcs->mkdir(h->opaque, dname);

        if (!retval)
            break;

        if (end == NULL)
            break;

        *end = '/';
        start = end + 1;
    } /* while */

    __PHYSFS_platformReleaseMutex(stateLock);
    return retval;
} /* doMkdir */


int PHYSFS_mkdir(const char *_dname)
{
    int retval = 0;
    char *dname;
    size_t len;

    BAIL_IF_MACRO(!_dname, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    len = strlen(_dname) + 1;
    dname = (char *) __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!dname, PHYSFS_ERR_OUT_OF_MEMORY, 0);
    retval = doMkdir(_dname, dname);
    __PHYSFS_smallFree(dname);
    return retval;
} /* PHYSFS_mkdir */


static int doDelete(const char *_fname, char *fname)
{
    int retval;
    DirHandle *h;
    BAIL_IF_MACRO(!sanitizePlatformIndependentPath(_fname, fname), ERRPASS, 0);

    __PHYSFS_platformGrabMutex(stateLock);

    BAIL_IF_MACRO_MUTEX(!writeDir, PHYSFS_ERR_NO_WRITE_DIR, stateLock, 0);
    h = writeDir;
    BAIL_IF_MACRO_MUTEX(!verifyPath(h, &fname, 0), ERRPASS, stateLock, 0);
    retval = h->funcs->remove(h->opaque, fname);

    __PHYSFS_platformReleaseMutex(stateLock);
    return retval;
} /* doDelete */


int PHYSFS_delete(const char *_fname)
{
    int retval;
    char *fname;
    size_t len;

    BAIL_IF_MACRO(!_fname, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    len = strlen(_fname) + 1;
    fname = (char *) __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!fname, PHYSFS_ERR_OUT_OF_MEMORY, 0);
    retval = doDelete(_fname, fname);
    __PHYSFS_smallFree(fname);
    return retval;
} /* PHYSFS_delete */


const char *PHYSFS_getRealDir(const char *_fname)
{
    const char *retval = NULL;
    char *fname = NULL;
    size_t len;

    BAIL_IF_MACRO(!_fname, PHYSFS_ERR_INVALID_ARGUMENT, NULL);
    len = strlen(_fname) + 1;
    fname = __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!fname, PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    if (sanitizePlatformIndependentPath(_fname, fname))
    {
        DirHandle *i;
        __PHYSFS_platformGrabMutex(stateLock);
        for (i = searchPath; i != NULL; i = i->next)
        {
            char *arcfname = fname;
            if (partOfMountPoint(i, arcfname))
            {
                retval = i->dirName;
                break;
            } /* if */
            else if (verifyPath(i, &arcfname, 0))
            {
                PHYSFS_Stat statbuf;
                int exists = 0;
                if (i->funcs->stat(i->opaque, arcfname, &exists, &statbuf))
                {
                    if (exists)
                        retval = i->dirName;
                    break;
                } /* if */
            } /* if */
        } /* for */
        __PHYSFS_platformReleaseMutex(stateLock);
    } /* if */

    __PHYSFS_smallFree(fname);
    return retval;
} /* PHYSFS_getRealDir */


static int locateInStringList(const char *str,
                              char **list,
                              PHYSFS_uint32 *pos)
{
    PHYSFS_uint32 len = *pos;
    PHYSFS_uint32 half_len;
    PHYSFS_uint32 lo = 0;
    PHYSFS_uint32 middle;
    int cmp;

    while (len > 0)
    {
        half_len = len >> 1;
        middle = lo + half_len;
        cmp = strcmp(list[middle], str);

        if (cmp == 0)  /* it's in the list already. */
            return 1;
        else if (cmp > 0)
            len = half_len;
        else
        {
            lo = middle + 1;
            len -= half_len + 1;
        } /* else */
    } /* while */

    *pos = lo;
    return 0;
} /* locateInStringList */


static void enumFilesCallback(void *data, const char *origdir, const char *str)
{
    PHYSFS_uint32 pos;
    void *ptr;
    char *newstr;
    EnumStringListCallbackData *pecd = (EnumStringListCallbackData *) data;

    /*
     * See if file is in the list already, and if not, insert it in there
     *  alphabetically...
     */
    pos = pecd->size;
    if (locateInStringList(str, pecd->list, &pos))
        return;  /* already in the list. */

    ptr = allocator.Realloc(pecd->list, (pecd->size + 2) * sizeof (char *));
    newstr = (char *) allocator.Malloc(strlen(str) + 1);
    if (ptr != NULL)
        pecd->list = (char **) ptr;

    if ((ptr == NULL) || (newstr == NULL))
        return;  /* better luck next time. */

    strcpy(newstr, str);

    if (pos != pecd->size)
    {
        memmove(&pecd->list[pos+1], &pecd->list[pos],
                 sizeof (char *) * ((pecd->size) - pos));
    } /* if */

    pecd->list[pos] = newstr;
    pecd->size++;
} /* enumFilesCallback */


char **PHYSFS_enumerateFiles(const char *path)
{
    EnumStringListCallbackData ecd;
    memset(&ecd, '\0', sizeof (ecd));
    ecd.list = (char **) allocator.Malloc(sizeof (char *));
    BAIL_IF_MACRO(!ecd.list, PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    PHYSFS_enumerateFilesCallback(path, enumFilesCallback, &ecd);
    ecd.list[ecd.size] = NULL;
    return ecd.list;
} /* PHYSFS_enumerateFiles */


/*
 * Broke out to seperate function so we can use stack allocation gratuitously.
 */
static void enumerateFromMountPoint(DirHandle *i, const char *arcfname,
                                    PHYSFS_EnumFilesCallback callback,
                                    const char *_fname, void *data)
{
    const size_t len = strlen(arcfname);
    char *ptr = NULL;
    char *end = NULL;
    const size_t slen = strlen(i->mountPoint) + 1;
    char *mountPoint = (char *) __PHYSFS_smallAlloc(slen);

    if (mountPoint == NULL)
        return;  /* oh well. */

    strcpy(mountPoint, i->mountPoint);
    ptr = mountPoint + ((len) ? len + 1 : 0);
    end = strchr(ptr, '/');
    assert(end);  /* should always find a terminating '/'. */
    *end = '\0';
    callback(data, _fname, ptr);
    __PHYSFS_smallFree(mountPoint);
} /* enumerateFromMountPoint */


typedef struct SymlinkFilterData
{
    PHYSFS_EnumFilesCallback callback;
    void *callbackData;
    DirHandle *dirhandle;
} SymlinkFilterData;

static void enumCallbackFilterSymLinks(void *_data, const char *origdir,
                                       const char *fname)
{
    const char *trimmedDir = (*origdir == '/') ? (origdir+1) : origdir;
    const size_t slen = strlen(trimmedDir) + strlen(fname) + 2;
    char *path = (char *) __PHYSFS_smallAlloc(slen);

    if (path != NULL)
    {
        SymlinkFilterData *data = (SymlinkFilterData *) _data;
        const DirHandle *dh = data->dirhandle;
        PHYSFS_Stat statbuf;
        int exists = 0;

        sprintf(path, "%s%s%s", trimmedDir, *trimmedDir ? "/" : "", fname);
        if (dh->funcs->stat(dh->opaque, path, &exists, &statbuf))
        {
            /* Pass it on to the application if it's not a symlink. */
            if (statbuf.filetype != PHYSFS_FILETYPE_SYMLINK)
                data->callback(data->callbackData, origdir, fname);
        } /* if */

        __PHYSFS_smallFree(path);
    } /* if */
} /* enumCallbackFilterSymLinks */


/* !!! FIXME: this should report error conditions. */
void PHYSFS_enumerateFilesCallback(const char *_fname,
                                   PHYSFS_EnumFilesCallback callback,
                                   void *data)
{
    size_t len;
    char *fname;

    BAIL_IF_MACRO(!_fname, PHYSFS_ERR_INVALID_ARGUMENT, ) /*0*/;
    BAIL_IF_MACRO(!callback, PHYSFS_ERR_INVALID_ARGUMENT, ) /*0*/;

    len = strlen(_fname) + 1;
    fname = (char *) __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!fname, PHYSFS_ERR_OUT_OF_MEMORY, ) /*0*/;

    if (sanitizePlatformIndependentPath(_fname, fname))
    {
        DirHandle *i;
        SymlinkFilterData filterdata;

        __PHYSFS_platformGrabMutex(stateLock);

        if (!allowSymLinks)
        {
            memset(&filterdata, '\0', sizeof (filterdata));
            filterdata.callback = callback;
            filterdata.callbackData = data;
        } /* if */

        for (i = searchPath; i != NULL; i = i->next)
        {
            char *arcfname = fname;
            if (partOfMountPoint(i, arcfname))
                enumerateFromMountPoint(i, arcfname, callback, _fname, data);

            else if (verifyPath(i, &arcfname, 0))
            {
                if ((!allowSymLinks) && (i->funcs->info.supportsSymlinks))
                {
                    filterdata.dirhandle = i;
                    i->funcs->enumerateFiles(i->opaque, arcfname,
                                             enumCallbackFilterSymLinks,
                                             _fname, &filterdata);
                } /* if */
                else
                {
                    i->funcs->enumerateFiles(i->opaque, arcfname,
                                             callback, _fname, data);
                } /* else */
            } /* else if */
        } /* for */
        __PHYSFS_platformReleaseMutex(stateLock);
    } /* if */

    __PHYSFS_smallFree(fname);
} /* PHYSFS_enumerateFilesCallback */


int PHYSFS_exists(const char *fname)
{
    return (PHYSFS_getRealDir(fname) != NULL);
} /* PHYSFS_exists */


PHYSFS_sint64 PHYSFS_getLastModTime(const char *fname)
{
    PHYSFS_Stat statbuf;
    BAIL_IF_MACRO(!PHYSFS_stat(fname, &statbuf), ERRPASS, -1);
    return statbuf.modtime;
} /* PHYSFS_getLastModTime */


int PHYSFS_isDirectory(const char *fname)
{
    PHYSFS_Stat statbuf;
    BAIL_IF_MACRO(!PHYSFS_stat(fname, &statbuf), ERRPASS, 0);
    return (statbuf.filetype == PHYSFS_FILETYPE_DIRECTORY);
} /* PHYSFS_isDirectory */


int PHYSFS_isSymbolicLink(const char *fname)
{
    PHYSFS_Stat statbuf;
    BAIL_IF_MACRO(!PHYSFS_stat(fname, &statbuf), ERRPASS, 0);
    return (statbuf.filetype == PHYSFS_FILETYPE_SYMLINK);
} /* PHYSFS_isSymbolicLink */


static PHYSFS_File *doOpenWrite(const char *_fname, int appending)
{
    FileHandle *fh = NULL;
    size_t len;
    char *fname;

    BAIL_IF_MACRO(!_fname, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    len = strlen(_fname) + 1;
    fname = (char *) __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!fname, PHYSFS_ERR_OUT_OF_MEMORY, 0);

    if (sanitizePlatformIndependentPath(_fname, fname))
    {
        PHYSFS_Io *io = NULL;
        DirHandle *h = NULL;
        const PHYSFS_Archiver *f;

        __PHYSFS_platformGrabMutex(stateLock);

        GOTO_IF_MACRO(!writeDir, PHYSFS_ERR_NO_WRITE_DIR, doOpenWriteEnd);

        h = writeDir;
        GOTO_IF_MACRO(!verifyPath(h, &fname, 0), ERRPASS, doOpenWriteEnd);

        f = h->funcs;
        if (appending)
            io = f->openAppend(h->opaque, fname);
        else
            io = f->openWrite(h->opaque, fname);

        GOTO_IF_MACRO(!io, ERRPASS, doOpenWriteEnd);

        fh = (FileHandle *) allocator.Malloc(sizeof (FileHandle));
        if (fh == NULL)
        {
            io->destroy(io);
            GOTO_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, doOpenWriteEnd);
        } /* if */
        else
        {
            memset(fh, '\0', sizeof (FileHandle));
            fh->io = io;
            fh->dirHandle = h;
            fh->next = openWriteList;
            openWriteList = fh;
        } /* else */

        doOpenWriteEnd:
        __PHYSFS_platformReleaseMutex(stateLock);
    } /* if */

    __PHYSFS_smallFree(fname);
    return ((PHYSFS_File *) fh);
} /* doOpenWrite */


PHYSFS_File *PHYSFS_openWrite(const char *filename)
{
    return doOpenWrite(filename, 0);
} /* PHYSFS_openWrite */


PHYSFS_File *PHYSFS_openAppend(const char *filename)
{
    return doOpenWrite(filename, 1);
} /* PHYSFS_openAppend */


PHYSFS_File *PHYSFS_openRead(const char *_fname)
{
    FileHandle *fh = NULL;
    char *fname;
    size_t len;

    BAIL_IF_MACRO(!_fname, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    len = strlen(_fname) + 1;
    fname = (char *) __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!fname, PHYSFS_ERR_OUT_OF_MEMORY, 0);

    if (sanitizePlatformIndependentPath(_fname, fname))
    {
        int fileExists = 0;
        DirHandle *i = NULL;
        PHYSFS_Io *io = NULL;

        __PHYSFS_platformGrabMutex(stateLock);

        GOTO_IF_MACRO(!searchPath, PHYSFS_ERR_NOT_FOUND, openReadEnd);

        for (i = searchPath; (i != NULL) && (!fileExists); i = i->next)
        {
            char *arcfname = fname;
            if (verifyPath(i, &arcfname, 0))
            {
                io = i->funcs->openRead(i->opaque, arcfname, &fileExists);
                if (io)
                    break;
            } /* if */
        } /* for */

        GOTO_IF_MACRO(!io, ERRPASS, openReadEnd);

        fh = (FileHandle *) allocator.Malloc(sizeof (FileHandle));
        if (fh == NULL)
        {
            io->destroy(io);
            GOTO_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, openReadEnd);
        } /* if */

        memset(fh, '\0', sizeof (FileHandle));
        fh->io = io;
        fh->forReading = 1;
        fh->dirHandle = i;
        fh->next = openReadList;
        openReadList = fh;

        openReadEnd:
        __PHYSFS_platformReleaseMutex(stateLock);
    } /* if */

    __PHYSFS_smallFree(fname);
    return ((PHYSFS_File *) fh);
} /* PHYSFS_openRead */


static int closeHandleInOpenList(FileHandle **list, FileHandle *handle)
{
    FileHandle *prev = NULL;
    FileHandle *i;
    int rc = 1;

    for (i = *list; i != NULL; i = i->next)
    {
        if (i == handle)  /* handle is in this list? */
        {
            PHYSFS_Io *io = handle->io;
            PHYSFS_uint8 *tmp = handle->buffer;
            rc = PHYSFS_flush((PHYSFS_File *) handle);
            if (!rc)
                return -1;
            io->destroy(io);

            if (tmp != NULL)  /* free any associated buffer. */
                allocator.Free(tmp);

            if (prev == NULL)
                *list = handle->next;
            else
                prev->next = handle->next;

            allocator.Free(handle);
            return 1;
        } /* if */
        prev = i;
    } /* for */

    return 0;
} /* closeHandleInOpenList */


int PHYSFS_close(PHYSFS_File *_handle)
{
    FileHandle *handle = (FileHandle *) _handle;
    int rc;

    __PHYSFS_platformGrabMutex(stateLock);

    /* -1 == close failure. 0 == not found. 1 == success. */
    rc = closeHandleInOpenList(&openReadList, handle);
    BAIL_IF_MACRO_MUTEX(rc == -1, ERRPASS, stateLock, 0);
    if (!rc)
    {
        rc = closeHandleInOpenList(&openWriteList, handle);
        BAIL_IF_MACRO_MUTEX(rc == -1, ERRPASS, stateLock, 0);
    } /* if */

    __PHYSFS_platformReleaseMutex(stateLock);
    BAIL_IF_MACRO(!rc, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    return 1;
} /* PHYSFS_close */


static PHYSFS_sint64 doBufferedRead(FileHandle *fh, void *buffer,
                                    PHYSFS_uint64 len)
{
    PHYSFS_Io *io = NULL;
    PHYSFS_sint64 retval = 0;
    PHYSFS_uint32 buffered = 0;
    PHYSFS_sint64 rc = 0;

    if (len == 0)
        return 0;

    buffered = fh->buffill - fh->bufpos;
    if (buffered >= len)  /* totally in the buffer, just copy and return! */
    {
        memcpy(buffer, fh->buffer + fh->bufpos, (size_t) len);
        fh->bufpos += (PHYSFS_uint32) len;
        return (PHYSFS_sint64) len;
    } /* else if */

    if (buffered > 0) /* partially in the buffer... */
    {
        memcpy(buffer, fh->buffer + fh->bufpos, (size_t) buffered);
        buffer = ((PHYSFS_uint8 *) buffer) + buffered;
        len -= buffered;
        retval = buffered;
        fh->buffill = fh->bufpos = 0;
    } /* if */

    /* if you got here, the buffer is drained and we still need bytes. */
    assert(len > 0);

    io = fh->io;
    if (len >= fh->bufsize)  /* need more than the buffer takes. */
    {
        /* leave buffer empty, go right to output instead. */
        rc = io->read(io, buffer, len);
        if (rc < 0)
            return ((retval == 0) ? rc : retval);
        return retval + rc;
    } /* if */

    /* need less than buffer can take. Fill buffer. */
    rc = io->read(io, fh->buffer, fh->bufsize);
    if (rc < 0)
        return ((retval == 0) ? rc : retval);

    assert(fh->bufpos == 0);
    fh->buffill = (PHYSFS_uint32) rc;
    rc = doBufferedRead(fh, buffer, len);  /* go from the start, again. */
    if (rc < 0)
        return ((retval == 0) ? rc : retval);

    return retval + rc;
} /* doBufferedRead */


PHYSFS_sint64 PHYSFS_read(PHYSFS_File *handle, void *buffer,
                          PHYSFS_uint32 size, PHYSFS_uint32 count)
{
    const PHYSFS_uint64 len = ((PHYSFS_uint64) size) * ((PHYSFS_uint64) count);
    const PHYSFS_sint64 retval = PHYSFS_readBytes(handle, buffer, len);
    return ( (retval <= 0) ? retval : (retval / ((PHYSFS_sint64) size)) );
} /* PHYSFS_read */


PHYSFS_sint64 PHYSFS_readBytes(PHYSFS_File *handle, void *buffer,
                               PHYSFS_uint64 len)
{
    FileHandle *fh = (FileHandle *) handle;

#ifdef PHYSFS_NO_64BIT_SUPPORT
    const PHYSFS_uint64 maxlen = __PHYSFS_UI64(0x7FFFFFFF);
#else
    const PHYSFS_uint64 maxlen = __PHYSFS_UI64(0x7FFFFFFFFFFFFFFF);
#endif

    if (!__PHYSFS_ui64FitsAddressSpace(len))
        BAIL_MACRO(PHYSFS_ERR_INVALID_ARGUMENT, -1);

    BAIL_IF_MACRO(len > maxlen, PHYSFS_ERR_INVALID_ARGUMENT, -1);
    BAIL_IF_MACRO(!fh->forReading, PHYSFS_ERR_OPEN_FOR_WRITING, -1);
    BAIL_IF_MACRO(len == 0, ERRPASS, 0);
    if (fh->buffer)
        return doBufferedRead(fh, buffer, len);

    return fh->io->read(fh->io, buffer, len);
} /* PHYSFS_readBytes */


static PHYSFS_sint64 doBufferedWrite(PHYSFS_File *handle, const void *buffer,
                                     PHYSFS_uint64 len)
{
    FileHandle *fh = (FileHandle *) handle;

    /* whole thing fits in the buffer? */
    if ( (((PHYSFS_uint64) fh->buffill) + len) < fh->bufsize )
    {
        memcpy(fh->buffer + fh->buffill, buffer, (size_t) len);
        fh->buffill += (PHYSFS_uint32) len;
        return (PHYSFS_sint64) len;
    } /* if */

    /* would overflow buffer. Flush and then write the new objects, too. */
    BAIL_IF_MACRO(!PHYSFS_flush(handle), ERRPASS, -1);
    return fh->io->write(fh->io, buffer, len);
} /* doBufferedWrite */


PHYSFS_sint64 PHYSFS_write(PHYSFS_File *handle, const void *buffer,
                           PHYSFS_uint32 size, PHYSFS_uint32 count)
{
    const PHYSFS_uint64 len = ((PHYSFS_uint64) size) * ((PHYSFS_uint64) count);
    const PHYSFS_sint64 retval = PHYSFS_writeBytes(handle, buffer, len);
    return ( (retval <= 0) ? retval : (retval / ((PHYSFS_sint64) size)) );
} /* PHYSFS_write */


PHYSFS_sint64 PHYSFS_writeBytes(PHYSFS_File *handle, const void *buffer,
                                PHYSFS_uint64 len)
{
    FileHandle *fh = (FileHandle *) handle;

#ifdef PHYSFS_NO_64BIT_SUPPORT
    const PHYSFS_uint64 maxlen = __PHYSFS_UI64(0x7FFFFFFF);
#else
    const PHYSFS_uint64 maxlen = __PHYSFS_UI64(0x7FFFFFFFFFFFFFFF);
#endif

    if (!__PHYSFS_ui64FitsAddressSpace(len))
        BAIL_MACRO(PHYSFS_ERR_INVALID_ARGUMENT, -1);

    BAIL_IF_MACRO(len > maxlen, PHYSFS_ERR_INVALID_ARGUMENT, -1);
    BAIL_IF_MACRO(fh->forReading, PHYSFS_ERR_OPEN_FOR_READING, -1);
    BAIL_IF_MACRO(len == 0, ERRPASS, 0);
    if (fh->buffer)
        return doBufferedWrite(handle, buffer, len);

    return fh->io->write(fh->io, buffer, len);
} /* PHYSFS_write */


int PHYSFS_eof(PHYSFS_File *handle)
{
    FileHandle *fh = (FileHandle *) handle;

    if (!fh->forReading)  /* never EOF on files opened for write/append. */
        return 0;

    /* can't be eof if buffer isn't empty */
    if (fh->bufpos == fh->buffill)
    {
        /* check the Io. */
        PHYSFS_Io *io = fh->io;
        const PHYSFS_sint64 pos = io->tell(io);
        const PHYSFS_sint64 len = io->length(io);
        if ((pos < 0) || (len < 0))
            return 0;  /* beats me. */
        return (pos >= len);
    } /* if */

    return 0;
} /* PHYSFS_eof */


PHYSFS_sint64 PHYSFS_tell(PHYSFS_File *handle)
{
    FileHandle *fh = (FileHandle *) handle;
    const PHYSFS_sint64 pos = fh->io->tell(fh->io);
    const PHYSFS_sint64 retval = fh->forReading ?
                                 (pos - fh->buffill) + fh->bufpos :
                                 (pos + fh->buffill);
    return retval;
} /* PHYSFS_tell */


int PHYSFS_seek(PHYSFS_File *handle, PHYSFS_uint64 pos)
{
    FileHandle *fh = (FileHandle *) handle;
    BAIL_IF_MACRO(!PHYSFS_flush(handle), ERRPASS, 0);

    if (fh->buffer && fh->forReading)
    {
        /* avoid throwing away our precious buffer if seeking within it. */
        PHYSFS_sint64 offset = pos - PHYSFS_tell(handle);
        if ( /* seeking within the already-buffered range? */
            ((offset >= 0) && (offset <= fh->buffill - fh->bufpos)) /* fwd */
            || ((offset < 0) && (-offset <= fh->bufpos)) /* backward */ )
        {
            fh->bufpos += (PHYSFS_uint32) offset;
            return 1; /* successful seek */
        } /* if */
    } /* if */

    /* we have to fall back to a 'raw' seek. */
    fh->buffill = fh->bufpos = 0;
    return fh->io->seek(fh->io, pos);
} /* PHYSFS_seek */


PHYSFS_sint64 PHYSFS_fileLength(PHYSFS_File *handle)
{
    PHYSFS_Io *io = ((FileHandle *) handle)->io;
    return io->length(io);
} /* PHYSFS_filelength */


int PHYSFS_setBuffer(PHYSFS_File *handle, PHYSFS_uint64 _bufsize)
{
    FileHandle *fh = (FileHandle *) handle;
    PHYSFS_uint32 bufsize;

    /* !!! FIXME: actually, why use 32 bits here? */
    /*BAIL_IF_MACRO(_bufsize > 0xFFFFFFFF, "buffer must fit in 32-bits", 0);*/
    BAIL_IF_MACRO(_bufsize > 0xFFFFFFFF, PHYSFS_ERR_INVALID_ARGUMENT, 0);
    bufsize = (PHYSFS_uint32) _bufsize;

    BAIL_IF_MACRO(!PHYSFS_flush(handle), ERRPASS, 0);

    /*
     * For reads, we need to move the file pointer to where it would be
     *  if we weren't buffering, so that the next read will get the
     *  right chunk of stuff from the file. PHYSFS_flush() handles writes.
     */
    if ((fh->forReading) && (fh->buffill != fh->bufpos))
    {
        PHYSFS_uint64 pos;
        const PHYSFS_sint64 curpos = fh->io->tell(fh->io);
        BAIL_IF_MACRO(curpos == -1, ERRPASS, 0);
        pos = ((curpos - fh->buffill) + fh->bufpos);
        BAIL_IF_MACRO(!fh->io->seek(fh->io, pos), ERRPASS, 0);
    } /* if */

    if (bufsize == 0)  /* delete existing buffer. */
    {
        if (fh->buffer)
        {
            allocator.Free(fh->buffer);
            fh->buffer = NULL;
        } /* if */
    } /* if */

    else
    {
        PHYSFS_uint8 *newbuf;
        newbuf = (PHYSFS_uint8 *) allocator.Realloc(fh->buffer, bufsize);
        BAIL_IF_MACRO(!newbuf, PHYSFS_ERR_OUT_OF_MEMORY, 0);
        fh->buffer = newbuf;
    } /* else */

    fh->bufsize = bufsize;
    fh->buffill = fh->bufpos = 0;
    return 1;
} /* PHYSFS_setBuffer */


int PHYSFS_flush(PHYSFS_File *handle)
{
    FileHandle *fh = (FileHandle *) handle;
    PHYSFS_Io *io;
    PHYSFS_sint64 rc;

    if ((fh->forReading) || (fh->bufpos == fh->buffill))
        return 1;  /* open for read or buffer empty are successful no-ops. */

    /* dump buffer to disk. */
    io = fh->io;
    rc = io->write(io, fh->buffer + fh->bufpos, fh->buffill - fh->bufpos);
    BAIL_IF_MACRO(rc <= 0, ERRPASS, 0);
    fh->bufpos = fh->buffill = 0;
    return io->flush(io);
} /* PHYSFS_flush */


int PHYSFS_stat(const char *_fname, PHYSFS_Stat *stat)
{
    int retval = 0;
    char *fname;
    size_t len;

    BAIL_IF_MACRO(!_fname, PHYSFS_ERR_INVALID_ARGUMENT, -1);
    BAIL_IF_MACRO(!stat, PHYSFS_ERR_INVALID_ARGUMENT, -1);
    len = strlen(_fname) + 1;
    fname = (char *) __PHYSFS_smallAlloc(len);
    BAIL_IF_MACRO(!fname, PHYSFS_ERR_OUT_OF_MEMORY, -1);

    /* set some sane defaults... */
    stat->filesize = -1;
    stat->modtime = -1;
    stat->createtime = -1;
    stat->accesstime = -1;
    stat->filetype = PHYSFS_FILETYPE_OTHER;
    stat->readonly = 1;  /* !!! FIXME */

    if (sanitizePlatformIndependentPath(_fname, fname))
    {
        if (*fname == '\0')
        {
            stat->filetype = PHYSFS_FILETYPE_DIRECTORY;
            stat->readonly = !writeDir; /* Writeable if we have a writeDir */
            retval = 1;
        } /* if */
        else
        {
            DirHandle *i;
            int exists = 0;
            __PHYSFS_platformGrabMutex(stateLock);
            for (i = searchPath; ((i != NULL) && (!exists)); i = i->next)
            {
                char *arcfname = fname;
                exists = partOfMountPoint(i, arcfname);
                if (exists)
                {
                    stat->filetype = PHYSFS_FILETYPE_DIRECTORY;
                    stat->readonly = 1;  /* !!! FIXME */
                    retval = 1;
                } /* if */
                else if (verifyPath(i, &arcfname, 0))
                {
                    /* !!! FIXME: this test is wrong and should be elsewhere. */
                    stat->readonly = !(writeDir &&
                                 (strcmp(writeDir->dirName, i->dirName) == 0));
                    retval = i->funcs->stat(i->opaque, arcfname, &exists, stat);
                } /* else if */
            } /* for */
            __PHYSFS_platformReleaseMutex(stateLock);
        } /* else */
    } /* if */

    __PHYSFS_smallFree(fname);
    return retval;
} /* PHYSFS_stat */


int __PHYSFS_readAll(PHYSFS_Io *io, void *buf, const PHYSFS_uint64 len)
{
    return (io->read(io, buf, len) == len);
} /* __PHYSFS_readAll */


void *__PHYSFS_initSmallAlloc(void *ptr, PHYSFS_uint64 len)
{
    void *useHeap = ((ptr == NULL) ? ((void *) 1) : ((void *) 0));
    if (useHeap)  /* too large for stack allocation or alloca() failed. */
        ptr = allocator.Malloc(len+sizeof (void *));

    if (ptr != NULL)
    {
        void **retval = (void **) ptr;
        /*printf("%s alloc'd (%d) bytes at (%p).\n",
                useHeap ? "heap" : "stack", (int) len, ptr);*/
        *retval = useHeap;
        return retval + 1;
    } /* if */

    return NULL;  /* allocation failed. */
} /* __PHYSFS_initSmallAlloc */


void __PHYSFS_smallFree(void *ptr)
{
    if (ptr != NULL)
    {
        void **block = ((void **) ptr) - 1;
        const int useHeap = (*block != 0);
        if (useHeap)
            allocator.Free(block);
        /*printf("%s free'd (%p).\n", useHeap ? "heap" : "stack", block);*/
    } /* if */
} /* __PHYSFS_smallFree */


int PHYSFS_setAllocator(const PHYSFS_Allocator *a)
{
    BAIL_IF_MACRO(initialized, PHYSFS_ERR_IS_INITIALIZED, 0);
    externalAllocator = (a != NULL);
    if (externalAllocator)
        memcpy(&allocator, a, sizeof (PHYSFS_Allocator));

    return 1;
} /* PHYSFS_setAllocator */


const PHYSFS_Allocator *PHYSFS_getAllocator(void)
{
    BAIL_IF_MACRO(!initialized, PHYSFS_ERR_NOT_INITIALIZED, NULL);
    return &allocator;
} /* PHYSFS_getAllocator */


static void *mallocAllocatorMalloc(PHYSFS_uint64 s)
{
    if (!__PHYSFS_ui64FitsAddressSpace(s))
        BAIL_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    #undef malloc
    return malloc((size_t) s);
} /* mallocAllocatorMalloc */


static void *mallocAllocatorRealloc(void *ptr, PHYSFS_uint64 s)
{
    if (!__PHYSFS_ui64FitsAddressSpace(s))
        BAIL_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, NULL);
    #undef realloc
    return realloc(ptr, (size_t) s);
} /* mallocAllocatorRealloc */


static void mallocAllocatorFree(void *ptr)
{
    #undef free
    free(ptr);
} /* mallocAllocatorFree */


static void setDefaultAllocator(void)
{
    assert(!externalAllocator);
    if (!__PHYSFS_platformSetDefaultAllocator(&allocator))
    {
        allocator.Init = NULL;
        allocator.Deinit = NULL;
        allocator.Malloc = mallocAllocatorMalloc;
        allocator.Realloc = mallocAllocatorRealloc;
        allocator.Free = mallocAllocatorFree;
    } /* if */
} /* setDefaultAllocator */

/* end of physfs.c ... */