pjs/modules/libjar/nsZipArchive.cpp

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C++

/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* ***** BEGIN LICENSE BLOCK *****
* Version: MPL 1.1/GPL 2.0/LGPL 2.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
* http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is Mozilla Communicator client code, released
* March 31, 1998.
*
* The Initial Developer of the Original Code is
* Netscape Communications Corporation.
* Portions created by the Initial Developer are Copyright (C) 1998
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
* Daniel Veditz <dveditz@netscape.com>
* Samir Gehani <sgehani@netscape.com>
* Mitch Stoltz <mstoltz@netscape.com>
* Jeroen Dobbelaere <jeroen.dobbelaere@acunia.com>
*
* Alternatively, the contents of this file may be used under the terms of
* either the GNU General Public License Version 2 or later (the "GPL"), or
* the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
* in which case the provisions of the GPL or the LGPL are applicable instead
* of those above. If you wish to allow use of your version of this file only
* under the terms of either the GPL or the LGPL, and not to allow others to
* use your version of this file under the terms of the MPL, indicate your
* decision by deleting the provisions above and replace them with the notice
* and other provisions required by the GPL or the LGPL. If you do not delete
* the provisions above, a recipient may use your version of this file under
* the terms of any one of the MPL, the GPL or the LGPL.
*
* ***** END LICENSE BLOCK ***** */
/*
* This module implements a simple archive extractor for the PKZIP format.
*
* The underlying nsZipArchive is NOT thread-safe. Do not pass references
* or pointers to it across thread boundaries.
*/
#ifndef STANDALONE
#include "nsWildCard.h"
#include "nscore.h"
#include "prmem.h"
#include "prio.h"
#include "plstr.h"
#include "prlog.h"
#include "prprf.h"
#define ZFILE_CREATE PR_WRONLY | PR_CREATE_FILE
#define READTYPE PRInt32
#include "zlib.h"
#include "nsISupportsUtils.h"
#include "nsRecyclingAllocator.h"
#include "nsPrintfCString.h"
/**
* Globals
*
* Global allocator used with zlib. Destroyed in module shutdown.
*/
#define NBUCKETS 6
#define BY4ALLOC_ITEMS 320
nsRecyclingAllocator *gZlibAllocator = NULL;
// For placement new used for arena allocations of zip file list
#include NEW_H
#else /* STANDALONE */
#ifdef XP_WIN
#include "windows.h"
#endif
#undef MOZILLA_CLIENT // undoes prtypes damage in zlib.h
#define ZFILE_CREATE "wb"
#define READTYPE PRUint32
#include "zlib.h"
#undef PR_PUBLIC_API
#include "zipstub.h"
#ifdef XP_MAC
#include <string.h>
#include <stdlib.h>
char * strdup(const char *src);
char * strdup(const char *src)
{
long len = strlen(src);
char *dup = (char *)malloc(len+1 * sizeof(char));
memcpy(dup, src, len+1);
return dup;
}
#endif
#endif /* STANDALONE */
#ifdef XP_UNIX
#include <sys/types.h>
#include <sys/stat.h>
#include <limits.h>
#include <unistd.h>
#elif defined(XP_WIN) || defined(XP_OS2)
#include <io.h>
#elif defined(XP_BEOS)
#include <unistd.h>
#endif
#ifndef XP_UNIX /* we need to have some constant defined in limits.h and unistd.h */
# ifndef S_IFMT
# define S_IFMT 0170000
# endif
# ifndef S_IFLNK
# define S_IFLNK 0120000
# endif
# ifndef PATH_MAX
# define PATH_MAX 1024
# endif
#endif /* XP_UNIX */
#include "zipfile.h"
#include "zipstruct.h"
#include "nsZipArchive.h"
static PRUint16 xtoint(unsigned char *ii);
static PRUint32 xtolong(unsigned char *ll);
static PRUint16 ExtractMode(PRUint32 ext_attr);
static PRBool IsSymlink(PRUint32 ext_attr);
/*---------------------------------------------
* C API wrapper for nsZipArchive
*--------------------------------------------*/
#ifdef STANDALONE
/**
* ZIP_OpenArchive
*
* opens the named zip/jar archive and returns a handle that
* represents the archive in other ZIP_ calls.
*
* @param zipname archive filename
* @param hZip receives handle if archive opened OK
* @return status code
*/
PR_PUBLIC_API(PRInt32) ZIP_OpenArchive(const char * zipname, void** hZip)
{
PRInt32 status;
/*--- error check args ---*/
if (hZip == 0)
return ZIP_ERR_PARAM;
/*--- NULL output to prevent use by bozos who don't check errors ---*/
*hZip = 0;
/*--- create and open the archive ---*/
nsZipArchive* zip = new nsZipArchive();
if (zip == 0)
return ZIP_ERR_MEMORY;
status = zip->OpenArchive(zipname);
if (status == ZIP_OK)
*hZip = NS_STATIC_CAST(void*,zip);
else
delete zip;
return status;
}
/**
* ZIP_TestArchive
*
* Tests the integrity of this open zip archive by extracting each
* item to memory and performing a CRC check.
*
* @param hZip handle obtained from ZIP_OpenArchive
* @return status code (success indicated by ZIP_OK)
*/
PR_PUBLIC_API(PRInt32) ZIP_TestArchive(void *hZip)
{
/*--- error check args ---*/
if (hZip == 0)
return ZIP_ERR_PARAM;
nsZipArchive* zip = NS_STATIC_CAST(nsZipArchive*,hZip);
if (zip->kMagic != ZIP_MAGIC)
return ZIP_ERR_PARAM; /* whatever it is isn't one of ours! */
/*--- test the archive ---*/
return zip->Test(NULL, zip->GetFd());
}
/**
* ZIP_CloseArchive
*
* closes zip archive and frees memory
* @param hZip handle obtained from ZIP_OpenArchive
* @return status code
*/
PR_PUBLIC_API(PRInt32) ZIP_CloseArchive(void** hZip)
{
/*--- error check args ---*/
if (hZip == 0 || *hZip == 0)
return ZIP_ERR_PARAM;
nsZipArchive* zip = NS_STATIC_CAST(nsZipArchive*,*hZip);
if (zip->kMagic != ZIP_MAGIC)
return ZIP_ERR_PARAM; /* whatever it is isn't one of ours! */
/*--- close the archive ---*/
*hZip = 0;
delete zip;
return ZIP_OK;
}
/**
* ZIP_ExtractFile
*
* extracts named file from an opened archive
*
* @param hZip handle obtained from ZIP_OpenArchive
* @param filename name of file in archive
* @param outname filename to extract to
*/
PR_PUBLIC_API(PRInt32) ZIP_ExtractFile(void* hZip, const char * filename, const char * outname)
{
/*--- error check args ---*/
if (hZip == 0)
return ZIP_ERR_PARAM;
nsZipArchive* zip = NS_STATIC_CAST(nsZipArchive*,hZip);
if (zip->kMagic != ZIP_MAGIC)
return ZIP_ERR_PARAM; /* whatever it is isn't one of ours! */
/*--- extract the file ---*/
return zip->ExtractFile(filename, outname, zip->GetFd());
}
/**
* ZIP_FindInit
*
* Initializes an enumeration of files in the archive
*
* @param hZip handle obtained from ZIP_OpenArchive
* @param pattern regexp to match files in archive, the usual shell expressions.
* NULL pattern also matches all files, faster than "*"
*/
PR_PUBLIC_API(void*) ZIP_FindInit(void* hZip, const char * pattern)
{
/*--- error check args ---*/
if (hZip == 0)
return 0;
nsZipArchive* zip = NS_STATIC_CAST(nsZipArchive*,hZip);
if (zip->kMagic != ZIP_MAGIC)
return 0; /* whatever it is isn't one of ours! */
/*--- initialize the pattern search ---*/
return zip->FindInit(pattern);
}
/**
* ZIP_FindNext
*
* Puts the next name in the passed buffer. Returns ZIP_ERR_SMALLBUF when
* the name is too large for the buffer, and ZIP_ERR_FNF when there are no
* more files that match the pattern
*
* @param hFind handle obtained from ZIP_FindInit
* @param outbuf buffer to receive next filename
* @param bufsize size of allocated buffer
*/
PR_PUBLIC_API(PRInt32) ZIP_FindNext(void* hFind, char * outbuf, PRUint16 bufsize)
{
PRInt32 status;
/*--- error check args ---*/
if (hFind == 0)
return ZIP_ERR_PARAM;
nsZipFind* find = NS_STATIC_CAST(nsZipFind*,hFind);
if (find->kMagic != ZIPFIND_MAGIC)
return ZIP_ERR_PARAM; /* whatever it is isn't one of ours! */
/*--- return next filename file ---*/
nsZipItem* item;
status = find->GetArchive()->FindNext(find, &item);
if (status == ZIP_OK)
{
PRUint16 namelen = (PRUint16)PL_strlen(item->name);
if (bufsize > namelen)
{
PL_strcpy(outbuf, item->name);
}
else
status = ZIP_ERR_SMALLBUF;
}
return status;
}
/**
* ZIP_FindFree
*
* Releases allocated memory associated with the find token
*
* @param hFind handle obtained from ZIP_FindInit
*/
PR_PUBLIC_API(PRInt32) ZIP_FindFree(void* hFind)
{
/*--- error check args ---*/
if (hFind == 0)
return ZIP_ERR_PARAM;
nsZipFind* find = NS_STATIC_CAST(nsZipFind*,hFind);
if (find->kMagic != ZIPFIND_MAGIC)
return ZIP_ERR_PARAM; /* whatever it is isn't one of ours! */
/* free the find structure */
return find->GetArchive()->FindFree(find);
}
#if defined XP_WIN
void ProcessWindowsMessages()
{
MSG msg;
while(PeekMessage(&msg, 0, 0, 0, PM_REMOVE))
{
TranslateMessage(&msg);
DispatchMessage(&msg);
}
}
#endif /* XP_WIN */
#else /* STANDALONE */
//***********************************************************
// Allocators for use with zlib
//
// These are allocators that are performance tuned for
// use with zlib. Our use of zlib for every file we read from
// the jar file when running navigator, we do these allocation.
// alloc 24
// alloc 64
// alloc 11520
// alloc 32768
// alloc 1216 [304x4] max
// alloc 76 [19x4]
// free 76 [19x4]
// alloc 1152 [288x4]
// free 1152 [288x4]
// free 1216 [304x4]
// alloc 28
// free 28
// free 32768
// free 11520
// free 64
// free 24
//
// The pool will allocate these as:
//
// 32,768
// 11,520
// 1,280 [320x4] - shared by first x4 alloc, 28
// 1,280 [320x4] - shared by second and third x4 alloc
// 64
// 24
// ------
// 46,936
//
// And almost all of the file reads happen serially. Hence this
// allocator tries to keep one set of memory needed for one file around
// and reused the same blocks for other file reads.
//
// The interesting question is when should be free this ?
// - memory pressure should be one.
// - after startup of navigator
// - after startup of mail
// In general, this allocator should be enabled before
// we startup and disabled after we startup if memory is a concern.
//***********************************************************
PR_STATIC_CALLBACK(void *)
zlibAlloc(void *opaque, uInt items, uInt size)
{
nsRecyclingAllocator *zallocator = (nsRecyclingAllocator *)opaque;
if (zallocator) {
// Bump up x4 allocations
PRUint32 realitems = items;
if (size == 4 && items < BY4ALLOC_ITEMS)
realitems = BY4ALLOC_ITEMS;
return zallocator->Calloc(realitems, size);
}
else
return calloc(items, size);
}
PR_STATIC_CALLBACK(void)
zlibFree(void *opaque, void *ptr)
{
nsRecyclingAllocator *zallocator = (nsRecyclingAllocator *)opaque;
if (zallocator)
zallocator->Free(ptr);
else
free(ptr);
return;
}
#endif /* STANDALONE */
//***********************************************************
// nsZipReadState -- public methods
//***********************************************************
void nsZipReadState::Init(nsZipItem* aZipItem, PRFileDesc* aFd)
{
PR_ASSERT(aFd);
mItem = aZipItem;
mCurPos = 0;
#ifndef STANDALONE
// take ownership of the file descriptor
mFd = aFd;
#endif
if (mItem->compression != STORED) {
memset(&mZs, 0, sizeof(mZs));
#ifndef STANDALONE
//-- ensure we have our zlib allocator for better performance
if (!gZlibAllocator) {
gZlibAllocator = new nsRecyclingAllocator(NBUCKETS, NS_DEFAULT_RECYCLE_TIMEOUT, "libjar");
}
mZs.zalloc = zlibAlloc;
mZs.zfree = zlibFree;
mZs.opaque = gZlibAllocator;
#endif
int zerr = inflateInit2(&mZs, -MAX_WBITS);
PR_ASSERT(zerr == Z_OK);
}
mCrc = crc32(0L, Z_NULL, 0);
}
//***********************************************************
// nsZipArchive -- public methods
//***********************************************************
#ifdef STANDALONE
//---------------------------------------------
// nsZipArchive::OpenArchive
//---------------------------------------------
PRInt32 nsZipArchive::OpenArchive(const char * aArchiveName)
{
//-- validate arguments
if (aArchiveName == 0 || *aArchiveName == '\0')
return ZIP_ERR_PARAM;
//-- open the physical file
mFd = PR_Open(aArchiveName, PR_RDONLY, 0000);
if (mFd == 0)
return ZIP_ERR_DISK;
//-- get table of contents for archive
return BuildFileList(GetFd());
}
#else
PRInt32 nsZipArchive::OpenArchiveWithFileDesc(PRFileDesc* fd)
{
//-- validate arguments
if (fd == 0)
return ZIP_ERR_PARAM;
//-- get table of contents for archive
return BuildFileList(fd);
}
#endif
//---------------------------------------------
// nsZipArchive::Test
//---------------------------------------------
PRInt32 nsZipArchive::Test(const char *aEntryName, PRFileDesc* aFd)
{
PRInt32 rv = ZIP_OK;
nsZipItem *currItem = 0;
if (aEntryName) // only test specified item
{
currItem = GetFileItem(aEntryName);
if(!currItem)
return ZIP_ERR_FNF;
rv = TestItem(currItem, aFd);
}
else // test all items in archive
{
nsZipFind *iterator = FindInit(NULL);
if (!iterator)
return ZIP_ERR_GENERAL;
// iterate over items in list
while (ZIP_OK == FindNext(iterator, &currItem))
{
rv = TestItem(currItem, aFd);
// check if crc check failed
if (rv != ZIP_OK)
break;
#if defined STANDALONE && defined XP_WIN
ProcessWindowsMessages();
#endif
}
FindFree(iterator);
}
return rv;
}
//---------------------------------------------
// nsZipArchive::CloseArchive
//---------------------------------------------
PRInt32 nsZipArchive::CloseArchive()
{
#ifndef STANDALONE
PL_FinishArenaPool(&mArena);
// CAUTION:
// We don't need to delete each of the nsZipItem as the memory for
// the zip item and the filename it holds are both allocated from the Arena.
// Hence, destroying the Arena is like destroying all the memory
// for all the nsZipItem in one shot. But if the ~nsZipItem is doing
// anything more than cleaning up memory, we should start calling it.
#else
// delete nsZipItems in table
nsZipItem* pItem;
for (int i = 0; i < ZIP_TABSIZE; ++i)
{
pItem = mFiles[i];
while (pItem != 0)
{
mFiles[i] = pItem->next;
delete pItem;
pItem = mFiles[i];
}
mFiles[i] = 0; // make sure we don't double-delete
}
if (mFd) {
PR_Close(mFd);
mFd = 0;
}
#endif
return ZIP_OK;
}
//---------------------------------------------
// nsZipArchive::GetItem
//---------------------------------------------
PRInt32 nsZipArchive::GetItem(const char * aFilename, nsZipItem **result)
{
//-- Parameter validity check
if (aFilename == 0)
return ZIP_ERR_PARAM;
nsZipItem* item;
//-- find file information
item = GetFileItem(aFilename);
if (item == 0)
{
return ZIP_ERR_FNF;
}
*result = item; // Return a pointer to the struct
return ZIP_OK;
}
//---------------------------------------------
// nsZipArchive::ReadInit
//---------------------------------------------
PRInt32 nsZipArchive::ReadInit(const char* zipEntry, nsZipReadState* aRead,
PRFileDesc* aFd)
{
//-- Parameter validity check
if (zipEntry == 0 || aRead == 0)
return ZIP_ERR_PARAM;
//-- find item
nsZipItem* item = GetFileItem(zipEntry);
if (!item) {
PR_Close(aFd);
return ZIP_ERR_FNF;
}
//-- verify we can handle the compression type
if (item->compression != DEFLATED && item->compression != STORED) {
PR_Close(aFd);
return ZIP_ERR_UNSUPPORTED;
}
SeekToItem(item, aFd);
#ifdef STANDALONE
// in standalone, nsZipArchive owns the file descriptor
mFd = aFd;
#endif
// in non-standalone builds, the nsZipReadState will take ownership
// of the file descriptor
aRead->Init(item, aFd);
return ZIP_OK;
}
//---------------------------------------------
// nsZipReadState::Available
//---------------------------------------------
PRUint32 nsZipReadState::Available()
{
if (mItem->compression == DEFLATED)
return (mItem->realsize - mZs.total_out);
return mItem->size - mCurPos;
}
//---------------------------------------------
// nsZipArchive::ExtractFile
//---------------------------------------------
PRInt32 nsZipArchive::ExtractFile(const char* zipEntry, const char* aOutname,
PRFileDesc* aFd)
{
//-- Find item in archive
nsZipItem* item = GetFileItem(zipEntry);
if (!item)
return ZIP_ERR_FNF;
// delete any existing file so that we overwrite the file permissions
PR_Delete(aOutname);
PRFileDesc* fOut = PR_Open(aOutname, ZFILE_CREATE, item->mode);
if (fOut == 0)
return ZIP_ERR_DISK;
#if defined(XP_UNIX) && defined(STANDALONE)
// When STANDALONE is defined, PR_Open ignores its 3d argument.
mode_t msk = umask(0);
umask(msk);
chmod(aOutname, item->mode & ~msk);
#endif
PRInt32 status = ExtractItemToFileDesc(item, fOut, aFd);
PR_Close(fOut);
if (status != ZIP_OK)
{
PR_Delete(aOutname);
}
#if defined(XP_UNIX) || defined(XP_BEOS)
else
{
if (ZIFLAG_SYMLINK & item->flags)
{
status = ResolveSymlink(aOutname, item);
}
}
#endif
return status;
}
PRInt32
nsZipArchive::ExtractItemToFileDesc(nsZipItem* item, PRFileDesc* outFD,
PRFileDesc* aFd)
{
//-- sanity check arguments
if (item == 0 || outFD == 0)
return ZIP_ERR_PARAM;
PRInt32 status;
//-- extract the file using the appropriate method
switch(item->compression)
{
case STORED:
status = CopyItemToDisk(item, outFD, aFd);
break;
case DEFLATED:
status = InflateItem(item, outFD, aFd);
break;
default:
//-- unsupported compression type
return ZIP_ERR_UNSUPPORTED;
}
return status;
}
//---------------------------------------------
// nsZipArchive::FindInit
//---------------------------------------------
nsZipFind* nsZipArchive::FindInit(const char * aPattern)
{
PRBool regExp = PR_FALSE;
char* pattern = 0;
// validate the pattern
if (aPattern)
{
switch (NS_WildCardValid((char*)aPattern))
{
case INVALID_SXP:
return 0;
case NON_SXP:
regExp = PR_FALSE;
break;
case VALID_SXP:
regExp = PR_TRUE;
break;
default:
// undocumented return value from RegExpValid!
PR_ASSERT(PR_FALSE);
return 0;
}
pattern = PL_strdup(aPattern);
if (!pattern)
return 0;
}
return new nsZipFind(this, pattern, regExp);
}
//---------------------------------------------
// nsZipArchive::FindNext
//---------------------------------------------
PRInt32 nsZipArchive::FindNext(nsZipFind* aFind, nsZipItem** aResult)
{
PRInt32 status;
PRBool found = PR_FALSE;
PRUint16 slot = aFind->mSlot;
nsZipItem* item = aFind->mItem;
if (aFind->mArchive != this)
return ZIP_ERR_PARAM;
// we start from last match, look for next
while (slot < ZIP_TABSIZE && !found)
{
if (item != 0)
item = item->next; // move to next in current chain
else
item = mFiles[slot]; // starting a new slot
if (item == 0)
{ // no more in this chain, move to next slot
++slot;
continue;
}
else if (aFind->mPattern == 0)
found = PR_TRUE; // always match
else if (aFind->mRegExp)
found = (NS_WildCardMatch(item->name, aFind->mPattern, PR_FALSE) == MATCH);
else
#if defined(STANDALONE) && defined(XP_MAC)
// simulate <regexp>* matches
found = (strncmp(item->name, aFind->mPattern, strlen(aFind->mPattern)) == 0);
#else
found = (PL_strcmp(item->name, aFind->mPattern) == 0);
#endif
}
if (found)
{
*aResult = item;
aFind->mSlot = slot;
aFind->mItem = item;
status = ZIP_OK;
}
else
status = ZIP_ERR_FNF;
return status;
}
//---------------------------------------------
// nsZipArchive::FindFree
//---------------------------------------------
PRInt32 nsZipArchive::FindFree(nsZipFind* aFind)
{
if (aFind->mArchive != this)
return ZIP_ERR_PARAM;
delete aFind;
return ZIP_OK;
}
#if defined(XP_UNIX) || defined(XP_BEOS)
//---------------------------------------------
// nsZipArchive::ResolveSymlink
//---------------------------------------------
PRInt32 nsZipArchive::ResolveSymlink(const char *path, nsZipItem *item)
{
PRInt32 status = ZIP_OK;
if (item->flags & ZIFLAG_SYMLINK)
{
char buf[PATH_MAX+1];
PRFileDesc * fIn = PR_Open(path, PR_RDONLY, 0000);
if (fIn)
{
PRInt32 length = PATH_MAX;
length = PR_Read(fIn,(void*)buf,length);
PR_Close(fIn);
fIn = 0;
if ( length <= 0
|| (buf[length] = 0, PR_Delete(path)) != 0
|| symlink(buf, path) != 0)
{
status = ZIP_ERR_DISK;
}
} else {
status = ZIP_ERR_DISK;
}
if (fIn)
{
PR_Close(fIn);
}
}
return status;
}
#endif
//***********************************************************
// nsZipArchive -- private implementation
//***********************************************************
#define BR_BUF_SIZE 1024 /* backward read buffer size */
//---------------------------------------------
// nsZipArchive::BuildFileList
//---------------------------------------------
PRInt32 nsZipArchive::BuildFileList(PRFileDesc* aFd)
{
PRInt32 status = ZIP_OK;
PRUint8 buf[4*BR_BUF_SIZE];
ZipEnd *End;
//-----------------------------------------------------------------------
// locate the central directory via the End record
//-----------------------------------------------------------------------
PRInt32 pos = 0L;
PRInt32 bufsize = 0;
//-- get archive size using end pos
pos = PR_Seek(aFd, 0, PR_SEEK_END);
#ifndef STANDALONE
if (pos <= 0)
#else
if (pos || ((pos = ftell(aFd)) <= 0))
#endif
status = ZIP_ERR_CORRUPT;
while (status == ZIP_OK)
{
//-- read backwards in 1K-sized chunks (unless file is less than 1K)
pos > BR_BUF_SIZE ? bufsize = BR_BUF_SIZE : bufsize = pos;
pos -= bufsize;
if (!ZIP_Seek(aFd, pos, PR_SEEK_SET))
{
status = ZIP_ERR_CORRUPT;
break;
}
if (PR_Read(aFd, buf, bufsize) != (READTYPE)bufsize)
{
status = ZIP_ERR_CORRUPT;
break;
}
//-- scan for ENDSIG
PRUint8 *endp = buf + bufsize;
PRUint32 endsig;
PRBool bEndsigFound = PR_FALSE;
for (endp -= ZIPEND_SIZE; endp >= buf; endp--)
{
endsig = xtolong(endp);
if (endsig == ENDSIG)
{
bEndsigFound = PR_TRUE;
break;
}
}
if (bEndsigFound)
{
End = (ZipEnd *) endp;
//-- set pos to start of central directory
pos = xtolong(End->offset_central_dir);
if (!ZIP_Seek(aFd, pos, PR_SEEK_SET))
status = ZIP_ERR_CORRUPT;
break;
}
if(pos <= 0)
//-- We're at the beginning of the file, and still no sign
//-- of the end signiture. File must be corrupted!
status = ZIP_ERR_CORRUPT;
//-- backward read must overlap ZipEnd length
pos += ZIPEND_SIZE;
} /* while looking for end signature */
//-------------------------------------------------------
// read the central directory headers
//-------------------------------------------------------
if (status == ZIP_OK)
{
//-- we think we found the central directory, read in the first chunk
pos = 0;
bufsize = PR_Read(aFd, &buf, sizeof(buf));
if (bufsize < (PRInt32)(ZIPCENTRAL_SIZE + ZIPEND_SIZE))
{
// We know we read the end sig and got pointed at the central
// directory--there should be at least this much
//
// (technically there can be a completely empty archive with only a
// ZipEnd structure; that's pointless and might as well be an error.)
status = ZIP_ERR_DISK;
}
//-- verify it's a central directory record
if (xtolong(buf) != CENTRALSIG)
status = ZIP_ERR_CORRUPT;
}
//-- loop through directory records
//
//-- we enter the loop positioned at a central directory record
//-- with enough valid data in the buffer to contain one
while (status == ZIP_OK)
{
//-------------------------------------------------------
// read the fixed-size data
//-------------------------------------------------------
ZipCentral* central = (ZipCentral*)(buf+pos);
PRUint32 namelen = xtoint(central->filename_len);
PRUint32 extralen = xtoint(central->extrafield_len);
PRUint32 commentlen = xtoint(central->commentfield_len);
#ifndef STANDALONE
// Arena allocate the nsZipItem
void *mem;
PL_ARENA_ALLOCATE(mem, &mArena, sizeof(nsZipItem));
// Use placement new to arena allcoate the nsZipItem
nsZipItem* item = mem ? new (mem) nsZipItem() : nsnull;
#else
nsZipItem* item = new nsZipItem();
#endif
if (!item)
{
status = ZIP_ERR_MEMORY;
break;
}
item->offset = xtolong(central->localhdr_offset);
item->compression = (PRUint8)xtoint(central->method);
#if defined(DEBUG)
/*
* Make sure our space optimization is non lossy.
*/
PR_ASSERT(xtoint(central->method) == (PRUint16)item->compression);
#endif
item->size = xtolong(central->size);
item->realsize = xtolong(central->orglen);
item->crc32 = xtolong(central->crc32);
PRUint32 external_attributes = xtolong(central->external_attributes);
item->mode = ExtractMode(external_attributes);
if (IsSymlink(external_attributes))
{
item->flags |= ZIFLAG_SYMLINK;
}
item->time = xtoint(central->time);
item->date = xtoint(central->date);
pos += ZIPCENTRAL_SIZE;
//-------------------------------------------------------
// get the item name
//-------------------------------------------------------
#ifndef STANDALONE
PL_ARENA_ALLOCATE(mem, &mArena, (namelen + 1));
item->name = (char *) mem;
if (!item->name)
{
status = ZIP_ERR_MEMORY;
// No need to delete name. It gets deleted only when the entire arena
// goes away.
break;
}
#else
item->name = new char[namelen + 1];
#endif
if (!item->name)
{
status = ZIP_ERR_MEMORY;
delete item;
break;
}
PRUint32 leftover = (PRUint32)(bufsize - pos);
if (leftover < namelen)
{
//-- not enough data left in buffer for the name.
//-- move leftover to top of buffer and read more
memcpy(buf, buf+pos, leftover);
bufsize = leftover + PR_Read(aFd, buf+leftover, bufsize-leftover);
pos = 0;
//-- make sure we were able to read enough
if ((PRUint32)bufsize < namelen)
{
status = ZIP_ERR_CORRUPT;
break;
}
}
memcpy(item->name, buf+pos, namelen);
item->name[namelen] = 0;
//-- add item to file table
PRUint32 hash = HashName(item->name);
item->next = mFiles[hash];
mFiles[hash] = item;
pos += namelen;
//-------------------------------------------------------
// set up to process the next item at the top of loop
//-------------------------------------------------------
leftover = (PRUint32)(bufsize - pos);
if (leftover < (extralen + commentlen + ZIPCENTRAL_SIZE))
{
//-- not enough data left to process at top of loop.
//-- move leftover and read more
memcpy(buf, buf+pos, leftover);
bufsize = leftover + PR_Read(aFd, buf+leftover, bufsize-leftover);
pos = 0;
}
//-- set position to start of next ZipCentral record
pos += extralen + commentlen;
PRUint32 sig = xtolong(buf+pos);
if (sig != CENTRALSIG)
{
//-- we must be done or else archive is corrupt
if (sig != ENDSIG)
status = ZIP_ERR_CORRUPT;
break;
}
//-- make sure we've read enough
if (bufsize < pos + ZIPCENTRAL_SIZE)
{
status = ZIP_ERR_CORRUPT;
break;
}
} /* while reading central directory records */
#if defined(DEBUG)
if (status != ZIP_OK) {
const char* msgs[] = { "ZIP_OK", "ZIP_ERR_GENERAL", "ZIP_ERR_MEMORY", "ZIP_ERR_DISK", "ZIP_ERR_CORRUPT", "ZIP_ERR_PARAM", "ZIP_ERR_FNF", "ZIP_ERR_UNSUPPORTED", "ZIP_ERR_SMALLBUF", "UNKNOWN" };
printf("nsZipArchive::BuildFileList status = %d '%s'\n", (int)status, msgs[(status <= 0 && status >= -8) ? -status : 9]);
}
#endif
return status;
}
//---------------------------------------------
// nsZipArchive::GetFileItem
//---------------------------------------------
nsZipItem* nsZipArchive::GetFileItem(const char * zipEntry)
{
PR_ASSERT(zipEntry != 0);
nsZipItem* item = mFiles[ HashName(zipEntry) ];
for (; item != 0; item = item->next)
{
if (0 == PL_strcmp(zipEntry, item->name))
break; //-- found it
}
return item;
}
//---------------------------------------------
// nsZipArchive::HashName
//---------------------------------------------
PRUint32 nsZipArchive::HashName(const char* aName)
{
PRUint32 val = 0;
PRUint8* c;
PR_ASSERT(aName != 0);
for (c = (PRUint8*)aName; *c != 0; c++) {
val = val*37 + *c;
}
return (val % ZIP_TABSIZE);
}
//---------------------------------------------
// nsZipArchive::SeekToItem
//---------------------------------------------
PRInt32 nsZipArchive::SeekToItem(const nsZipItem* aItem, PRFileDesc* aFd)
{
PR_ASSERT (aItem);
PRFileDesc* fd = aFd;
//-- the first time an item is used we need to calculate its offset
if (!(aItem->flags & ZIFLAG_DATAOFFSET))
{
//-- aItem->offset contains the header offset, not the data offset.
//-- read local header to get variable length values and calculate
//-- the real data offset
//--
//-- NOTE: extralen is different in central header and local header
//-- for archives created using the Unix "zip" utility. To set
//-- the offset accurately we need the _local_ extralen.
if (!ZIP_Seek(fd, aItem->offset, PR_SEEK_SET))
return ZIP_ERR_CORRUPT;
ZipLocal Local;
if (PR_Read(fd, (char*)&Local, ZIPLOCAL_SIZE) != (READTYPE) ZIPLOCAL_SIZE
|| xtolong(Local.signature) != LOCALSIG)
{
//-- read error or local header not found
return ZIP_ERR_CORRUPT;
}
((nsZipItem*)aItem)->offset += ZIPLOCAL_SIZE +
xtoint(Local.filename_len) +
xtoint(Local.extrafield_len);
((nsZipItem*)aItem)->flags |= ZIFLAG_DATAOFFSET;
}
//-- move to start of file in archive
if (!ZIP_Seek(fd, aItem->offset, PR_SEEK_SET))
return ZIP_ERR_CORRUPT;
return ZIP_OK;
}
//---------------------------------------------
// nsZipArchive::CopyItemToDisk
//---------------------------------------------
PRInt32
nsZipArchive::CopyItemToDisk(const nsZipItem* aItem,
PRFileDesc* fOut, PRFileDesc* aFd)
{
PRInt32 status = ZIP_OK;
PRUint32 chunk, pos, size, crc;
PR_ASSERT(aItem != 0 && fOut != 0);
PRFileDesc* fd = aFd;
//-- move to the start of file's data
if (SeekToItem(aItem, aFd) != ZIP_OK)
return ZIP_ERR_CORRUPT;
char buf[ZIP_BUFLEN];
//-- initialize crc
crc = crc32(0L, Z_NULL, 0);
//-- copy chunks until file is done
size = aItem->size;
for (pos=0; pos < size; pos += chunk)
{
chunk = (pos+ZIP_BUFLEN <= size) ? ZIP_BUFLEN : size - pos;
if (PR_Read(fd, buf, chunk) != (READTYPE)chunk)
{
//-- unexpected end of data in archive
status = ZIP_ERR_CORRUPT;
break;
}
//-- incrementally update crc32
crc = crc32(crc, (const unsigned char*)buf, chunk);
if (PR_Write(fOut, buf, chunk) < (READTYPE)chunk)
{
//-- Couldn't write all the data (disk full?)
status = ZIP_ERR_DISK;
break;
}
}
//-- verify crc32
if ((status == ZIP_OK) && (crc != aItem->crc32))
status = ZIP_ERR_CORRUPT;
return status;
}
#ifndef STANDALONE
//------------------------------------------
// nsZipArchive::Read
//------------------------------------------
PRInt32
nsZipReadState::Read(char* aBuffer, PRUint32 aCount,
PRUint32* aBytesRead)
{
if (!aBuffer)
return ZIP_ERR_GENERAL;
PRInt32 result;
if (!Available()) {
*aBytesRead = 0;
return ZIP_OK;
}
switch (mItem->compression) {
case DEFLATED:
result = ContinueInflate(aBuffer, aCount, aBytesRead);
break;
case STORED:
result = ContinueCopy(aBuffer, aCount, aBytesRead);
break;
default:
result = ZIP_ERR_UNSUPPORTED;
}
// be agressive about closing!
// note that sometimes, we will close mFd before we've finished
// deflating - this is because zlib buffers the input
if (mCurPos >= mItem->size && mFd) {
PR_Close(mFd);
mFd = NULL;
}
return result;
}
PRInt32
nsZipReadState::ContinueInflate(char* aBuffer, PRUint32 aCount,
PRUint32* aBytesRead)
{
// just some stuff that will be helpful later
const PRUint32 inSize = mItem->size;
const PRUint32 outSize = mItem->realsize;
int zerr = Z_OK;
//-- inflate loop
const PRUint32 oldTotalOut = mZs.total_out;
mZs.next_out = (unsigned char*)aBuffer;
mZs.avail_out = ((mZs.total_out + aCount) < outSize) ?
aCount : (outSize - mZs.total_out);
// make sure we aren't reading too much
PR_ASSERT(mZs.avail_out <= aCount);
*aBytesRead = 0;
while (mZs.avail_out != 0 && zerr == Z_OK) {
if (mZs.avail_in == 0 && mCurPos < inSize) {
// time to fill the buffer!
PRUint32 bytesToRead = ((mCurPos + ZIP_BUFLEN) < inSize) ?
ZIP_BUFLEN : inSize - mCurPos;
PR_ASSERT(mFd);
PRInt32 bytesRead = PR_Read(mFd, mReadBuf, bytesToRead);
if (bytesRead < 0) {
zerr = Z_ERRNO;
break;
}
mCrc = crc32(mCrc, mReadBuf, bytesRead);
mCurPos += bytesRead;
// now reset the state
mZs.next_in = mReadBuf;
mZs.avail_in = bytesRead;
}
#if 0
// stop returning valid data as soon as we know we have a bad CRC
if (mCurPos >= inSize &&
mCrc != mItem->crc32) {
// asserting because while this rarely happens, you definitely
// want to catch it in debug builds!
PR_ASSERT(0);
return ZIP_ERR_CORRUPT;
}
#endif
// now inflate
zerr = inflate(&mZs, Z_PARTIAL_FLUSH);
}
if ((zerr != Z_OK) && (zerr != Z_STREAM_END))
return ZIP_ERR_CORRUPT;
*aBytesRead = (mZs.total_out - oldTotalOut);
// be aggressive about closing the stream
// for some reason we don't always get Z_STREAM_END
if (zerr == Z_STREAM_END || mZs.total_out == mItem->realsize) {
inflateEnd(&mZs);
}
return ZIP_OK;
}
PRInt32 nsZipReadState::ContinueCopy(char* aBuf,
PRUint32 aCount,
PRUint32* aBytesRead)
{
// we still use the fields of mZs, we just use memcpy rather than inflate
if (mCurPos + aCount > mItem->realsize)
aCount = (mItem->realsize - mCurPos);
PR_ASSERT(mFd);
PRInt32 bytesRead = PR_Read(mFd, aBuf, aCount);
if (bytesRead < 0)
return ZIP_ERR_DISK;
mCurPos += bytesRead;
*aBytesRead = bytesRead;
return ZIP_OK;
}
#endif
//---------------------------------------------
// nsZipArchive::InflateItem
//---------------------------------------------
PRInt32 nsZipArchive::InflateItem(const nsZipItem* aItem, PRFileDesc* fOut, PRFileDesc* aFd)
/*
* This function either inflates an archive item to disk, to the
* file specified by aOutname, or into a buffer specified by
* bigBuf. bigBuf then gets copied into the "real" output
* buffer a chunk at a time by ReadInflatedItem(). Memory-wise,
* this is inefficient, since it stores an entire copy of the
* decompressed item in memory, then copies it to the caller's
* buffer. A more memory-efficient implementation is possible,
* in which the outbuf in this function could be returned
* directly, but implementing it would be complex.
*/
{
PRInt32 status = ZIP_OK;
PRUint32 chunk, inpos, outpos, size, crc;
PRUint32 bigBufSize=0;
z_stream zs;
int zerr;
PRBool bInflating = PR_FALSE;
PRBool bRead;
PRBool bWrote;
PRBool bToFile;
Bytef* old_next_out;
// -- if aOutname is null, we'll be writing to a buffer instead of a file
if (fOut != 0)
{
PR_ASSERT(aItem != 0);
bToFile = PR_TRUE;
}
else
{
// -- Writing to a buffer, so bigBuf must not be null.
PR_ASSERT(aItem);
bToFile = PR_FALSE;
bigBufSize = aItem->realsize;
}
//-- move to the start of file's data
if (SeekToItem(aItem, aFd) != ZIP_OK)
return ZIP_ERR_CORRUPT;
//-- allocate deflation buffers
Bytef inbuf[ZIP_BUFLEN];
Bytef outbuf[ZIP_BUFLEN];
//-- set up the inflate
memset(&zs, 0, sizeof(zs));
#ifndef STANDALONE
//-- ensure we have our zlib allocator for better performance
if (!gZlibAllocator) {
gZlibAllocator = new nsRecyclingAllocator(NBUCKETS, NS_DEFAULT_RECYCLE_TIMEOUT, "libjar");
}
zs.zalloc = zlibAlloc;
zs.zfree = zlibFree;
zs.opaque = gZlibAllocator;
#endif
zerr = inflateInit2(&zs, -MAX_WBITS);
if (zerr != Z_OK)
{
status = ZIP_ERR_GENERAL;
goto cleanup;
}
bInflating = PR_TRUE;
//-- inflate loop
size = aItem->size;
outpos = inpos = 0;
zs.next_out = outbuf;
zs.avail_out = ZIP_BUFLEN;
crc = crc32(0L, Z_NULL, 0);
while (zerr == Z_OK)
{
bRead = PR_FALSE;
bWrote = PR_FALSE;
if (zs.avail_in == 0 && zs.total_in < size)
{
//-- no data to inflate yet still more in file:
//-- read another chunk of compressed data
inpos = zs.total_in; // input position
chunk = (inpos + ZIP_BUFLEN <= size) ? ZIP_BUFLEN : size - inpos;
if (PR_Read(aFd, inbuf, chunk) != (READTYPE)chunk)
{
//-- unexpected end of data
status = ZIP_ERR_CORRUPT;
break;
}
zs.next_in = inbuf;
zs.avail_in = chunk;
bRead = PR_TRUE;
}
if (zs.avail_out == 0)
{
//-- write inflated buffer to disk and make space
if (PR_Write(fOut, outbuf, ZIP_BUFLEN) < ZIP_BUFLEN)
{
//-- Couldn't write all the data (disk full?)
status = ZIP_ERR_DISK;
break;
}
outpos = zs.total_out;
zs.next_out = outbuf;
zs.avail_out = ZIP_BUFLEN;
bWrote = PR_TRUE;
}
if(bRead || bWrote)
{
old_next_out = zs.next_out;
zerr = inflate(&zs, Z_PARTIAL_FLUSH);
//-- incrementally update crc32
crc = crc32(crc, (const unsigned char*)old_next_out, zs.next_out - old_next_out);
}
else
zerr = Z_STREAM_END;
#if defined STANDALONE && defined XP_WIN
ProcessWindowsMessages();
#endif
} // while
//-- verify crc32
if ((status == ZIP_OK) && (crc != aItem->crc32))
{
status = ZIP_ERR_CORRUPT;
goto cleanup;
}
//-- write last inflated bit to disk
if (zerr == Z_STREAM_END && outpos < zs.total_out)
{
chunk = zs.total_out - outpos;
if (PR_Write(fOut, outbuf, chunk) < (READTYPE)chunk)
status = ZIP_ERR_DISK;
}
//-- convert zlib error to return value
if (status == ZIP_OK && zerr != Z_OK && zerr != Z_STREAM_END)
{
status = (zerr == Z_MEM_ERROR) ? ZIP_ERR_MEMORY : ZIP_ERR_CORRUPT;
}
//-- if found no errors make sure we've converted the whole thing
PR_ASSERT(status != ZIP_OK || zs.total_in == aItem->size);
PR_ASSERT(status != ZIP_OK || zs.total_out == aItem->realsize);
cleanup:
if (bInflating)
{
//-- free zlib internal state
inflateEnd(&zs);
}
return status;
}
//---------------------------------------------
// nsZipArchive::TestItem
//---------------------------------------------
PRInt32 nsZipArchive::TestItem(const nsZipItem* aItem, PRFileDesc* aFd)
{
Bytef inbuf[ZIP_BUFLEN], outbuf[ZIP_BUFLEN], *old_next_out;
PRUint32 size, chunk=0, inpos, crc;
PRInt32 status = ZIP_OK;
int zerr = Z_OK;
z_stream zs;
PRBool bInflating = PR_FALSE;
PRBool bRead;
PRBool bWrote;
//-- param checks
if (!aItem)
return ZIP_ERR_PARAM;
if (aItem->compression != STORED && aItem->compression != DEFLATED)
return ZIP_ERR_UNSUPPORTED;
//-- move to the start of file's data
if (SeekToItem(aItem, aFd) != ZIP_OK)
return ZIP_ERR_CORRUPT;
//-- set up the inflate if DEFLATED
if (aItem->compression == DEFLATED)
{
memset(&zs, 0, sizeof(zs));
zerr = inflateInit2(&zs, -MAX_WBITS);
if (zerr != Z_OK)
{
status = ZIP_ERR_GENERAL;
goto cleanup;
}
else
{
zs.next_out = outbuf;
zs.avail_out = ZIP_BUFLEN;
}
bInflating = PR_TRUE;
}
//-- initialize crc checksum
crc = crc32(0L, Z_NULL, 0);
size = aItem->size;
inpos = 0;
//-- read in ZIP_BUFLEN-sized chunks of item
//-- inflating if item is DEFLATED
while (zerr == Z_OK)
{
bRead = PR_FALSE; // used to check if new data to inflate
bWrote = PR_FALSE; // used to reset zs.next_out to outbuf
// when outbuf fills up
//-- read to inbuf
if (aItem->compression == DEFLATED)
{
if (zs.avail_in == 0 && zs.total_in < size)
{
//-- no data to inflate yet still more in file:
//-- read another chunk of compressed data
inpos = zs.total_in; // input position
chunk = (inpos + ZIP_BUFLEN <= size) ? ZIP_BUFLEN : size - inpos;
if (PR_Read(aFd, inbuf, chunk) != (READTYPE)chunk)
{
//-- unexpected end of data
status = ZIP_ERR_CORRUPT;
break;
}
zs.next_in = inbuf;
zs.avail_in = chunk;
bRead = PR_TRUE;
}
if (zs.avail_out == 0)
{
//-- reuse output buffer
zs.next_out = outbuf;
zs.avail_out = ZIP_BUFLEN;
bWrote = PR_TRUE; // mimic writing to disk/memory
}
}
else
{
if (inpos < size)
{
//-- read a chunk in
chunk = (inpos + ZIP_BUFLEN <= size) ? ZIP_BUFLEN : size - inpos;
if (PR_Read(aFd, inbuf, chunk) != (READTYPE)chunk)
{
//-- unexpected end of data
status = ZIP_ERR_CORRUPT;
break;
}
inpos += chunk;
}
else
{
//-- finished reading STORED item
break;
}
}
//-- inflate if item is DEFLATED
if (aItem->compression == DEFLATED)
{
if (bRead || bWrote)
{
old_next_out = zs.next_out;
zerr = inflate(&zs, Z_PARTIAL_FLUSH);
//-- incrementally update crc checksum
crc = crc32(crc, (const unsigned char*)old_next_out, zs.next_out - old_next_out);
}
else
zerr = Z_STREAM_END;
}
//-- else just use input buffer containing data from STORED item
else
{
//-- incrementally update crc checksum
crc = crc32(crc, (const unsigned char*)inbuf, chunk);
}
}
//-- convert zlib error to return value
if (status == ZIP_OK && zerr != Z_OK && zerr != Z_STREAM_END)
{
status = (zerr == Z_MEM_ERROR) ? ZIP_ERR_MEMORY : ZIP_ERR_CORRUPT;
goto cleanup;
}
//-- verify computed crc checksum against header info crc
if (status == ZIP_OK && crc != aItem->crc32)
{
status = ZIP_ERR_CORRUPT;
}
cleanup:
if (bInflating)
{
//-- free zlib internal state
inflateEnd(&zs);
}
return status;
}
//------------------------------------------
// nsZipArchive constructor and destructor
//------------------------------------------
MOZ_DECL_CTOR_COUNTER(nsZipArchive)
nsZipArchive::nsZipArchive()
: kMagic(ZIP_MAGIC), kArenaBlockSize(1*1024)
#ifdef STANDALONE
, mFd(0)
#endif
{
MOZ_COUNT_CTOR(nsZipArchive);
// initialize the table to NULL
memset(mFiles, 0, sizeof mFiles);
#ifndef STANDALONE
// Initialize our arena
PL_INIT_ARENA_POOL(&mArena, "ZipArena", kArenaBlockSize);
#endif
}
nsZipArchive::~nsZipArchive()
{
CloseArchive();
MOZ_COUNT_DTOR(nsZipArchive);
}
//------------------------------------------
// nsZipItem constructor and destructor
//------------------------------------------
nsZipItem::nsZipItem() : name(0), offset(0), next(0), flags(0)
{
}
nsZipItem::~nsZipItem()
{
#ifdef STANDALONE
if (name != 0)
{
delete [] name;
name = 0;
}
#endif
}
//------------------------------------------
// nsZipReadState
//------------------------------------------
MOZ_DECL_CTOR_COUNTER(nsZipReadState)
//------------------------------------------
// nsZipFind constructor and destructor
//------------------------------------------
MOZ_DECL_CTOR_COUNTER(nsZipFind)
nsZipFind::nsZipFind(nsZipArchive* aZip, char* aPattern, PRBool aRegExp)
: kMagic(ZIPFIND_MAGIC),
mArchive(aZip),
mPattern(aPattern),
mSlot(0),
mItem(0),
mRegExp(aRegExp)
{
MOZ_COUNT_CTOR(nsZipFind);
}
nsZipFind::~nsZipFind()
{
if (mPattern != 0)
PL_strfree(mPattern);
MOZ_COUNT_DTOR(nsZipFind);
}
//------------------------------------------
// nsZipFind::GetArchive
//------------------------------------------
nsZipArchive* nsZipFind::GetArchive()
{
if (!mArchive)
return NULL;
return mArchive;
}
//------------------------------------------
// helper functions
//------------------------------------------
/*
* x t o i n t
*
* Converts a two byte ugly endianed integer
* to our platform's integer.
*/
static PRUint16 xtoint (unsigned char *ii)
{
return (PRUint16) ((ii [0]) | (ii [1] << 8));
}
/*
* x t o l o n g
*
* Converts a four byte ugly endianed integer
* to our platform's integer.
*/
static PRUint32 xtolong (unsigned char *ll)
{
PRUint32 ret;
ret = (
(((PRUint32) ll [0]) << 0) |
(((PRUint32) ll [1]) << 8) |
(((PRUint32) ll [2]) << 16) |
(((PRUint32) ll [3]) << 24)
);
return ret;
}
/*
* ExtractMode
*
* Extracts bits 17-24 from a 32-bit unsigned long
* representation of the external attributes field.
* Subsequently it tacks on the implicit user-read
* bit.
*/
static PRUint16 ExtractMode(PRUint32 ext_attr)
{
ext_attr &= 0x00FF0000;
ext_attr >>= 16;
ext_attr |= 0x00000100;
return (PRUint16) ext_attr;
}
/*
*
* Return true if the attributes are for a symbolic link
*
*/
static PRBool IsSymlink(PRUint32 ext_attr)
{
return (((ext_attr>>16) & S_IFMT) == S_IFLNK) ? PR_TRUE : PR_FALSE;
}
#ifndef STANDALONE
PRTime
nsZipItem::GetModTime()
{
char buffer[17];
PRUint16 aDate = this->date;
PRUint16 aTime = this->time;
PR_snprintf(buffer, sizeof(buffer), "%02d/%02d/%04d %02d:%02d",
((aDate >> 5) & 0x0F), (aDate & 0x1F), (aDate >> 9) + 1980,
((aTime >> 11) & 0x1F), ((aTime >> 5) & 0x3F));
PRTime result;
PR_ParseTimeString(buffer, PR_FALSE, &result);
return result;
}
#endif