here a personal experimental mockup of how I imagine wrapping world edges should look like. bouncing one could be similar just with mirrored stuff. please test and share opinion. note: you might wanna disable auto-cam
/*
* High-level PhysicsFS archiver for simple unpacked file formats.
*
* This is a framework that basic archivers build on top of. It's for simple
* formats that can just hand back a list of files and the offsets of their
* uncompressed data. There are an alarming number of formats like this.
*
* RULES: Archive entries must be uncompressed, must not have separate subdir
* entries (but can have subdirs), must be case insensitive LOW ASCII
* filenames <= 56 bytes. No symlinks, etc. We can relax some of these rules
* as necessary.
*
* Please see the file LICENSE.txt in the source's root directory.
*
* This file written by Ryan C. Gordon.
*/
#define __PHYSICSFS_INTERNAL__
#include "physfs_internal.h"
typedef struct
{
PHYSFS_Io *io;
PHYSFS_uint32 entryCount;
UNPKentry *entries;
} UNPKinfo;
typedef struct
{
PHYSFS_Io *io;
UNPKentry *entry;
PHYSFS_uint32 curPos;
} UNPKfileinfo;
void UNPK_closeArchive(PHYSFS_Dir *opaque)
{
UNPKinfo *info = ((UNPKinfo *) opaque);
info->io->destroy(info->io);
allocator.Free(info->entries);
allocator.Free(info);
} /* UNPK_closeArchive */
static PHYSFS_sint64 UNPK_read(PHYSFS_Io *io, void *buffer, PHYSFS_uint64 len)
{
UNPKfileinfo *finfo = (UNPKfileinfo *) io->opaque;
const UNPKentry *entry = finfo->entry;
const PHYSFS_uint64 bytesLeft = (PHYSFS_uint64)(entry->size-finfo->curPos);
PHYSFS_sint64 rc;
if (bytesLeft < len)
len = bytesLeft;
rc = finfo->io->read(finfo->io, buffer, len);
if (rc > 0)
finfo->curPos += (PHYSFS_uint32) rc;
return rc;
} /* UNPK_read */
static PHYSFS_sint64 UNPK_write(PHYSFS_Io *io, const void *b, PHYSFS_uint64 len)
{
BAIL_MACRO(PHYSFS_ERR_READ_ONLY, -1);
} /* UNPK_write */
static PHYSFS_sint64 UNPK_tell(PHYSFS_Io *io)
{
return ((UNPKfileinfo *) io->opaque)->curPos;
} /* UNPK_tell */
static int UNPK_seek(PHYSFS_Io *io, PHYSFS_uint64 offset)
{
UNPKfileinfo *finfo = (UNPKfileinfo *) io->opaque;
const UNPKentry *entry = finfo->entry;
int rc;
BAIL_IF_MACRO(offset >= entry->size, PHYSFS_ERR_PAST_EOF, 0);
rc = finfo->io->seek(finfo->io, entry->startPos + offset);
if (rc)
finfo->curPos = (PHYSFS_uint32) offset;
return rc;
} /* UNPK_seek */
static PHYSFS_sint64 UNPK_length(PHYSFS_Io *io)
{
const UNPKfileinfo *finfo = (UNPKfileinfo *) io->opaque;
return ((PHYSFS_sint64) finfo->entry->size);
} /* UNPK_length */
static PHYSFS_Io *UNPK_duplicate(PHYSFS_Io *_io)
{
UNPKfileinfo *origfinfo = (UNPKfileinfo *) _io->opaque;
PHYSFS_Io *io = NULL;
PHYSFS_Io *retval = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
UNPKfileinfo *finfo = (UNPKfileinfo *) allocator.Malloc(sizeof (UNPKfileinfo));
GOTO_IF_MACRO(!retval, PHYSFS_ERR_OUT_OF_MEMORY, UNPK_duplicate_failed);
GOTO_IF_MACRO(!finfo, PHYSFS_ERR_OUT_OF_MEMORY, UNPK_duplicate_failed);
io = origfinfo->io->duplicate(origfinfo->io);
if (!io) goto UNPK_duplicate_failed;
finfo->io = io;
finfo->entry = origfinfo->entry;
finfo->curPos = 0;
memcpy(retval, _io, sizeof (PHYSFS_Io));
retval->opaque = finfo;
return retval;
UNPK_duplicate_failed:
if (finfo != NULL) allocator.Free(finfo);
if (retval != NULL) allocator.Free(retval);
if (io != NULL) io->destroy(io);
return NULL;
} /* UNPK_duplicate */
static int UNPK_flush(PHYSFS_Io *io) { return 1; /* no write support. */ }
static void UNPK_destroy(PHYSFS_Io *io)
{
UNPKfileinfo *finfo = (UNPKfileinfo *) io->opaque;
finfo->io->destroy(finfo->io);
allocator.Free(finfo);
allocator.Free(io);
} /* UNPK_destroy */
static const PHYSFS_Io UNPK_Io =
{
CURRENT_PHYSFS_IO_API_VERSION, NULL,
UNPK_read,
UNPK_write,
UNPK_seek,
UNPK_tell,
UNPK_length,
UNPK_duplicate,
UNPK_flush,
UNPK_destroy
};
static int entryCmp(void *_a, size_t one, size_t two)
{
if (one != two)
{
const UNPKentry *a = (const UNPKentry *) _a;
return __PHYSFS_stricmpASCII(a[one].name, a[two].name);
} /* if */
return 0;
} /* entryCmp */
static void entrySwap(void *_a, size_t one, size_t two)
{
if (one != two)
{
UNPKentry tmp;
UNPKentry *first = &(((UNPKentry *) _a)[one]);
UNPKentry *second = &(((UNPKentry *) _a)[two]);
memcpy(&tmp, first, sizeof (UNPKentry));
memcpy(first, second, sizeof (UNPKentry));
memcpy(second, &tmp, sizeof (UNPKentry));
} /* if */
} /* entrySwap */
static PHYSFS_sint32 findStartOfDir(UNPKinfo *info, const char *path,
int stop_on_first_find)
{
PHYSFS_sint32 lo = 0;
PHYSFS_sint32 hi = (PHYSFS_sint32) (info->entryCount - 1);
PHYSFS_sint32 middle;
PHYSFS_uint32 dlen = (PHYSFS_uint32) strlen(path);
PHYSFS_sint32 retval = -1;
const char *name;
int rc;
if (*path == '\0') /* root dir? */
return 0;
if ((dlen > 0) && (path[dlen - 1] == '/')) /* ignore trailing slash. */
dlen--;
while (lo <= hi)
{
middle = lo + ((hi - lo) / 2);
name = info->entries[middle].name;
rc = __PHYSFS_strnicmpASCII(path, name, dlen);
if (rc == 0)
{
char ch = name[dlen];
if (ch < '/') /* make sure this isn't just a substr match. */
rc = -1;
else if (ch > '/')
rc = 1;
else
{
if (stop_on_first_find) /* Just checking dir's existance? */
return middle;
if (name[dlen + 1] == '\0') /* Skip initial dir entry. */
return (middle + 1);
/* there might be more entries earlier in the list. */
retval = middle;
hi = middle - 1;
} /* else */
} /* if */
if (rc > 0)
lo = middle + 1;
else
hi = middle - 1;
} /* while */
return retval;
} /* findStartOfDir */
/*
* Moved to seperate function so we can use alloca then immediately throw
* away the allocated stack space...
*/
static void doEnumCallback(PHYSFS_EnumFilesCallback cb, void *callbackdata,
const char *odir, const char *str, PHYSFS_sint32 ln)
{
char *newstr = __PHYSFS_smallAlloc(ln + 1);
if (newstr == NULL)
return;
memcpy(newstr, str, ln);
newstr[ln] = '\0';
cb(callbackdata, odir, newstr);
__PHYSFS_smallFree(newstr);
} /* doEnumCallback */
void UNPK_enumerateFiles(PHYSFS_Dir *opaque, const char *dname,
int omitSymLinks, PHYSFS_EnumFilesCallback cb,
const char *origdir, void *callbackdata)
{
UNPKinfo *info = ((UNPKinfo *) opaque);
PHYSFS_sint32 dlen, dlen_inc, max, i;
i = findStartOfDir(info, dname, 0);
if (i == -1) /* no such directory. */
return;
dlen = (PHYSFS_sint32) strlen(dname);
if ((dlen > 0) && (dname[dlen - 1] == '/')) /* ignore trailing slash. */
dlen--;
dlen_inc = ((dlen > 0) ? 1 : 0) + dlen;
max = (PHYSFS_sint32) info->entryCount;
while (i < max)
{
char *add;
char *ptr;
PHYSFS_sint32 ln;
char *e = info->entries[i].name;
if ((dlen) &&
((__PHYSFS_strnicmpASCII(e, dname, dlen)) || (e[dlen] != '/')))
{
break; /* past end of this dir; we're done. */
} /* if */
add = e + dlen_inc;
ptr = strchr(add, '/');
ln = (PHYSFS_sint32) ((ptr) ? ptr-add : strlen(add));
doEnumCallback(cb, callbackdata, origdir, add, ln);
ln += dlen_inc; /* point past entry to children... */
/* increment counter and skip children of subdirs... */
while ((++i < max) && (ptr != NULL))
{
char *e_new = info->entries[i].name;
if ((__PHYSFS_strnicmpASCII(e, e_new, ln) != 0) ||
(e_new[ln] != '/'))
{
break;
} /* if */
} /* while */
} /* while */
} /* UNPK_enumerateFiles */
/*
* This will find the UNPKentry associated with a path in platform-independent
* notation. Directories don't have UNPKentries associated with them, but
* (*isDir) will be set to non-zero if a dir was hit.
*/
static UNPKentry *findEntry(const UNPKinfo *info, const char *path, int *isDir)
{
UNPKentry *a = info->entries;
PHYSFS_sint32 pathlen = (PHYSFS_sint32) strlen(path);
PHYSFS_sint32 lo = 0;
PHYSFS_sint32 hi = (PHYSFS_sint32) (info->entryCount - 1);
PHYSFS_sint32 middle;
const char *thispath = NULL;
int rc;
while (lo <= hi)
{
middle = lo + ((hi - lo) / 2);
thispath = a[middle].name;
rc = __PHYSFS_strnicmpASCII(path, thispath, pathlen);
if (rc > 0)
lo = middle + 1;
else if (rc < 0)
hi = middle - 1;
else /* substring match...might be dir or entry or nothing. */
{
if (isDir != NULL)
{
*isDir = (thispath[pathlen] == '/');
if (*isDir)
return NULL;
} /* if */
if (thispath[pathlen] == '\0') /* found entry? */
return &a[middle];
/* adjust search params, try again. */
else if (thispath[pathlen] > '/')
hi = middle - 1;
else
lo = middle + 1;
} /* if */
} /* while */
if (isDir != NULL)
*isDir = 0;
BAIL_MACRO(PHYSFS_ERR_NO_SUCH_PATH, NULL);
} /* findEntry */
PHYSFS_Io *UNPK_openRead(PHYSFS_Dir *opaque, const char *fnm, int *fileExists)
{
PHYSFS_Io *retval = NULL;
UNPKinfo *info = (UNPKinfo *) opaque;
UNPKfileinfo *finfo = NULL;
int isdir = 0;
UNPKentry *entry = findEntry(info, fnm, &isdir);
*fileExists = (entry != NULL);
GOTO_IF_MACRO(isdir, PHYSFS_ERR_NOT_A_FILE, UNPK_openRead_failed);
GOTO_IF_MACRO(!entry, ERRPASS, UNPK_openRead_failed);
retval = (PHYSFS_Io *) allocator.Malloc(sizeof (PHYSFS_Io));
GOTO_IF_MACRO(!retval, PHYSFS_ERR_OUT_OF_MEMORY, UNPK_openRead_failed);
finfo = (UNPKfileinfo *) allocator.Malloc(sizeof (UNPKfileinfo));
GOTO_IF_MACRO(!finfo, PHYSFS_ERR_OUT_OF_MEMORY, UNPK_openRead_failed);
finfo->io = info->io->duplicate(info->io);
GOTO_IF_MACRO(!finfo->io, ERRPASS, UNPK_openRead_failed);
if (!finfo->io->seek(finfo->io, entry->startPos))
goto UNPK_openRead_failed;
finfo->curPos = 0;
finfo->entry = entry;
memcpy(retval, &UNPK_Io, sizeof (*retval));
retval->opaque = finfo;
return retval;
UNPK_openRead_failed:
if (finfo != NULL)
{
if (finfo->io != NULL)
finfo->io->destroy(finfo->io);
allocator.Free(finfo);
} /* if */
if (retval != NULL)
allocator.Free(retval);
return NULL;
} /* UNPK_openRead */
PHYSFS_Io *UNPK_openWrite(PHYSFS_Dir *opaque, const char *name)
{
BAIL_MACRO(PHYSFS_ERR_READ_ONLY, NULL);
} /* UNPK_openWrite */
PHYSFS_Io *UNPK_openAppend(PHYSFS_Dir *opaque, const char *name)
{
BAIL_MACRO(PHYSFS_ERR_READ_ONLY, NULL);
} /* UNPK_openAppend */
int UNPK_remove(PHYSFS_Dir *opaque, const char *name)
{
BAIL_MACRO(PHYSFS_ERR_READ_ONLY, 0);
} /* UNPK_remove */
int UNPK_mkdir(PHYSFS_Dir *opaque, const char *name)
{
BAIL_MACRO(PHYSFS_ERR_READ_ONLY, 0);
} /* UNPK_mkdir */
int UNPK_stat(PHYSFS_Dir *opaque, const char *filename,
int *exists, PHYSFS_Stat *stat)
{
int isDir = 0;
const UNPKinfo *info = (const UNPKinfo *) opaque;
const UNPKentry *entry = findEntry(info, filename, &isDir);
if (isDir)
{
*exists = 1;
stat->filetype = PHYSFS_FILETYPE_DIRECTORY;
stat->filesize = 0;
} /* if */
else if (entry != NULL)
{
*exists = 1;
stat->filetype = PHYSFS_FILETYPE_REGULAR;
stat->filesize = entry->size;
} /* else if */
else
{
*exists = 0;
return 0;
} /* else */
stat->modtime = -1;
stat->createtime = -1;
stat->accesstime = -1;
stat->readonly = 1;
return 1;
} /* UNPK_stat */
PHYSFS_Dir *UNPK_openArchive(PHYSFS_Io *io, UNPKentry *e,
const PHYSFS_uint32 num)
{
UNPKinfo *info = (UNPKinfo *) allocator.Malloc(sizeof (UNPKinfo));
if (info == NULL)
{
allocator.Free(e);
BAIL_MACRO(PHYSFS_ERR_OUT_OF_MEMORY, NULL);
} /* if */
__PHYSFS_sort(e, (size_t) num, entryCmp, entrySwap);
info->io = io;
info->entryCount = num;
info->entries = e;
return info;
} /* UNPK_openArchive */
/* end of archiver_unpacked.c ... */