platform_system_core/libziparchive/zip_archive.cc
Adam Lesinski d987c9dd9e ZipWriter: Keep LFH and CFH in sync
We change the GPB in the LocalFileHeader if the entry can not
have a trailing DataDescriptor. Make sure to patch the
CentralFileHeader to have the same bits set.

Modify ZipArchive to check that the data descriptor bit is consistent
between Central and Local file headers.

(cherry-pick of commit e0eca55fe6)

Test: make ziparchive-tests
Bug: 36686974
Change-Id: Ied167570abcf6426b1c678cd40123e5ad65909db
2017-04-11 01:45:25 +00:00

1229 lines
40 KiB
C++

/*
* Copyright (C) 2008 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (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.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*
* Read-only access to Zip archives, with minimal heap allocation.
*/
#define LOG_TAG "ziparchive"
#include <assert.h>
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <limits.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <memory>
#include <vector>
#include <android-base/file.h>
#include <android-base/logging.h>
#include <android-base/macros.h> // TEMP_FAILURE_RETRY may or may not be in unistd
#include <android-base/memory.h>
#include <log/log.h>
#include <utils/Compat.h>
#include <utils/FileMap.h>
#include "ziparchive/zip_archive.h"
#include "zlib.h"
#include "entry_name_utils-inl.h"
#include "zip_archive_common.h"
#include "zip_archive_private.h"
using android::base::get_unaligned;
// This is for windows. If we don't open a file in binary mode, weird
// things will happen.
#ifndef O_BINARY
#define O_BINARY 0
#endif
// The maximum number of bytes to scan backwards for the EOCD start.
static const uint32_t kMaxEOCDSearch = kMaxCommentLen + sizeof(EocdRecord);
static const char* kErrorMessages[] = {
"Unknown return code.",
"Iteration ended",
"Zlib error",
"Invalid file",
"Invalid handle",
"Duplicate entries in archive",
"Empty archive",
"Entry not found",
"Invalid offset",
"Inconsistent information",
"Invalid entry name",
"I/O Error",
"File mapping failed"
};
static const int32_t kErrorMessageUpperBound = 0;
static const int32_t kIterationEnd = -1;
// We encountered a Zlib error when inflating a stream from this file.
// Usually indicates file corruption.
static const int32_t kZlibError = -2;
// The input file cannot be processed as a zip archive. Usually because
// it's too small, too large or does not have a valid signature.
static const int32_t kInvalidFile = -3;
// An invalid iteration / ziparchive handle was passed in as an input
// argument.
static const int32_t kInvalidHandle = -4;
// The zip archive contained two (or possibly more) entries with the same
// name.
static const int32_t kDuplicateEntry = -5;
// The zip archive contains no entries.
static const int32_t kEmptyArchive = -6;
// The specified entry was not found in the archive.
static const int32_t kEntryNotFound = -7;
// The zip archive contained an invalid local file header pointer.
static const int32_t kInvalidOffset = -8;
// The zip archive contained inconsistent entry information. This could
// be because the central directory & local file header did not agree, or
// if the actual uncompressed length or crc32 do not match their declared
// values.
static const int32_t kInconsistentInformation = -9;
// An invalid entry name was encountered.
static const int32_t kInvalidEntryName = -10;
// An I/O related system call (read, lseek, ftruncate, map) failed.
static const int32_t kIoError = -11;
// We were not able to mmap the central directory or entry contents.
static const int32_t kMmapFailed = -12;
static const int32_t kErrorMessageLowerBound = -13;
/*
* A Read-only Zip archive.
*
* We want "open" and "find entry by name" to be fast operations, and
* we want to use as little memory as possible. We memory-map the zip
* central directory, and load a hash table with pointers to the filenames
* (which aren't null-terminated). The other fields are at a fixed offset
* from the filename, so we don't need to extract those (but we do need
* to byte-read and endian-swap them every time we want them).
*
* It's possible that somebody has handed us a massive (~1GB) zip archive,
* so we can't expect to mmap the entire file.
*
* To speed comparisons when doing a lookup by name, we could make the mapping
* "private" (copy-on-write) and null-terminate the filenames after verifying
* the record structure. However, this requires a private mapping of
* every page that the Central Directory touches. Easier to tuck a copy
* of the string length into the hash table entry.
*/
/*
* Round up to the next highest power of 2.
*
* Found on http://graphics.stanford.edu/~seander/bithacks.html.
*/
static uint32_t RoundUpPower2(uint32_t val) {
val--;
val |= val >> 1;
val |= val >> 2;
val |= val >> 4;
val |= val >> 8;
val |= val >> 16;
val++;
return val;
}
static uint32_t ComputeHash(const ZipString& name) {
uint32_t hash = 0;
uint16_t len = name.name_length;
const uint8_t* str = name.name;
while (len--) {
hash = hash * 31 + *str++;
}
return hash;
}
/*
* Convert a ZipEntry to a hash table index, verifying that it's in a
* valid range.
*/
static int64_t EntryToIndex(const ZipString* hash_table,
const uint32_t hash_table_size,
const ZipString& name) {
const uint32_t hash = ComputeHash(name);
// NOTE: (hash_table_size - 1) is guaranteed to be non-negative.
uint32_t ent = hash & (hash_table_size - 1);
while (hash_table[ent].name != NULL) {
if (hash_table[ent] == name) {
return ent;
}
ent = (ent + 1) & (hash_table_size - 1);
}
ALOGV("Zip: Unable to find entry %.*s", name.name_length, name.name);
return kEntryNotFound;
}
/*
* Add a new entry to the hash table.
*/
static int32_t AddToHash(ZipString *hash_table, const uint64_t hash_table_size,
const ZipString& name) {
const uint64_t hash = ComputeHash(name);
uint32_t ent = hash & (hash_table_size - 1);
/*
* We over-allocated the table, so we're guaranteed to find an empty slot.
* Further, we guarantee that the hashtable size is not 0.
*/
while (hash_table[ent].name != NULL) {
if (hash_table[ent] == name) {
// We've found a duplicate entry. We don't accept it
ALOGW("Zip: Found duplicate entry %.*s", name.name_length, name.name);
return kDuplicateEntry;
}
ent = (ent + 1) & (hash_table_size - 1);
}
hash_table[ent].name = name.name;
hash_table[ent].name_length = name.name_length;
return 0;
}
static int32_t MapCentralDirectory0(const char* debug_file_name, ZipArchive* archive,
off64_t file_length, off64_t read_amount,
uint8_t* scan_buffer) {
const off64_t search_start = file_length - read_amount;
if(!archive->mapped_zip.ReadAtOffset(scan_buffer, read_amount, search_start)) {
ALOGE("Zip: read %" PRId64 " from offset %" PRId64 " failed",
static_cast<int64_t>(read_amount), static_cast<int64_t>(search_start));
return kIoError;
}
/*
* Scan backward for the EOCD magic. In an archive without a trailing
* comment, we'll find it on the first try. (We may want to consider
* doing an initial minimal read; if we don't find it, retry with a
* second read as above.)
*/
int i = read_amount - sizeof(EocdRecord);
for (; i >= 0; i--) {
if (scan_buffer[i] == 0x50) {
uint32_t* sig_addr = reinterpret_cast<uint32_t*>(&scan_buffer[i]);
if (get_unaligned<uint32_t>(sig_addr) == EocdRecord::kSignature) {
ALOGV("+++ Found EOCD at buf+%d", i);
break;
}
}
}
if (i < 0) {
ALOGD("Zip: EOCD not found, %s is not zip", debug_file_name);
return kInvalidFile;
}
const off64_t eocd_offset = search_start + i;
const EocdRecord* eocd = reinterpret_cast<const EocdRecord*>(scan_buffer + i);
/*
* Verify that there's no trailing space at the end of the central directory
* and its comment.
*/
const off64_t calculated_length = eocd_offset + sizeof(EocdRecord)
+ eocd->comment_length;
if (calculated_length != file_length) {
ALOGW("Zip: %" PRId64 " extraneous bytes at the end of the central directory",
static_cast<int64_t>(file_length - calculated_length));
return kInvalidFile;
}
/*
* Grab the CD offset and size, and the number of entries in the
* archive and verify that they look reasonable.
*/
if (static_cast<off64_t>(eocd->cd_start_offset) + eocd->cd_size > eocd_offset) {
ALOGW("Zip: bad offsets (dir %" PRIu32 ", size %" PRIu32 ", eocd %" PRId64 ")",
eocd->cd_start_offset, eocd->cd_size, static_cast<int64_t>(eocd_offset));
#if defined(__ANDROID__)
if (eocd->cd_start_offset + eocd->cd_size <= eocd_offset) {
android_errorWriteLog(0x534e4554, "31251826");
}
#endif
return kInvalidOffset;
}
if (eocd->num_records == 0) {
ALOGW("Zip: empty archive?");
return kEmptyArchive;
}
ALOGV("+++ num_entries=%" PRIu32 " dir_size=%" PRIu32 " dir_offset=%" PRIu32,
eocd->num_records, eocd->cd_size, eocd->cd_start_offset);
/*
* It all looks good. Create a mapping for the CD, and set the fields
* in archive.
*/
if (!archive->InitializeCentralDirectory(debug_file_name,
static_cast<off64_t>(eocd->cd_start_offset),
static_cast<size_t>(eocd->cd_size))) {
ALOGE("Zip: failed to intialize central directory.\n");
return kMmapFailed;
}
archive->num_entries = eocd->num_records;
archive->directory_offset = eocd->cd_start_offset;
return 0;
}
/*
* Find the zip Central Directory and memory-map it.
*
* On success, returns 0 after populating fields from the EOCD area:
* directory_offset
* directory_ptr
* num_entries
*/
static int32_t MapCentralDirectory(const char* debug_file_name, ZipArchive* archive) {
// Test file length. We use lseek64 to make sure the file
// is small enough to be a zip file (Its size must be less than
// 0xffffffff bytes).
off64_t file_length = archive->mapped_zip.GetFileLength();
if (file_length == -1) {
return kInvalidFile;
}
if (file_length > static_cast<off64_t>(0xffffffff)) {
ALOGV("Zip: zip file too long %" PRId64, static_cast<int64_t>(file_length));
return kInvalidFile;
}
if (file_length < static_cast<off64_t>(sizeof(EocdRecord))) {
ALOGV("Zip: length %" PRId64 " is too small to be zip", static_cast<int64_t>(file_length));
return kInvalidFile;
}
/*
* Perform the traditional EOCD snipe hunt.
*
* We're searching for the End of Central Directory magic number,
* which appears at the start of the EOCD block. It's followed by
* 18 bytes of EOCD stuff and up to 64KB of archive comment. We
* need to read the last part of the file into a buffer, dig through
* it to find the magic number, parse some values out, and use those
* to determine the extent of the CD.
*
* We start by pulling in the last part of the file.
*/
off64_t read_amount = kMaxEOCDSearch;
if (file_length < read_amount) {
read_amount = file_length;
}
std::vector<uint8_t> scan_buffer(read_amount);
int32_t result = MapCentralDirectory0(debug_file_name, archive, file_length, read_amount,
scan_buffer.data());
return result;
}
/*
* Parses the Zip archive's Central Directory. Allocates and populates the
* hash table.
*
* Returns 0 on success.
*/
static int32_t ParseZipArchive(ZipArchive* archive) {
const uint8_t* const cd_ptr = archive->central_directory.GetBasePtr();
const size_t cd_length = archive->central_directory.GetMapLength();
const uint16_t num_entries = archive->num_entries;
/*
* Create hash table. We have a minimum 75% load factor, possibly as
* low as 50% after we round off to a power of 2. There must be at
* least one unused entry to avoid an infinite loop during creation.
*/
archive->hash_table_size = RoundUpPower2(1 + (num_entries * 4) / 3);
archive->hash_table = reinterpret_cast<ZipString*>(calloc(archive->hash_table_size,
sizeof(ZipString)));
/*
* Walk through the central directory, adding entries to the hash
* table and verifying values.
*/
const uint8_t* const cd_end = cd_ptr + cd_length;
const uint8_t* ptr = cd_ptr;
for (uint16_t i = 0; i < num_entries; i++) {
const CentralDirectoryRecord* cdr =
reinterpret_cast<const CentralDirectoryRecord*>(ptr);
if (cdr->record_signature != CentralDirectoryRecord::kSignature) {
ALOGW("Zip: missed a central dir sig (at %" PRIu16 ")", i);
return -1;
}
if (ptr + sizeof(CentralDirectoryRecord) > cd_end) {
ALOGW("Zip: ran off the end (at %" PRIu16 ")", i);
return -1;
}
const off64_t local_header_offset = cdr->local_file_header_offset;
if (local_header_offset >= archive->directory_offset) {
ALOGW("Zip: bad LFH offset %" PRId64 " at entry %" PRIu16,
static_cast<int64_t>(local_header_offset), i);
return -1;
}
const uint16_t file_name_length = cdr->file_name_length;
const uint16_t extra_length = cdr->extra_field_length;
const uint16_t comment_length = cdr->comment_length;
const uint8_t* file_name = ptr + sizeof(CentralDirectoryRecord);
/* check that file name is valid UTF-8 and doesn't contain NUL (U+0000) characters */
if (!IsValidEntryName(file_name, file_name_length)) {
return -1;
}
/* add the CDE filename to the hash table */
ZipString entry_name;
entry_name.name = file_name;
entry_name.name_length = file_name_length;
const int add_result = AddToHash(archive->hash_table,
archive->hash_table_size, entry_name);
if (add_result != 0) {
ALOGW("Zip: Error adding entry to hash table %d", add_result);
return add_result;
}
ptr += sizeof(CentralDirectoryRecord) + file_name_length + extra_length + comment_length;
if ((ptr - cd_ptr) > static_cast<int64_t>(cd_length)) {
ALOGW("Zip: bad CD advance (%tu vs %zu) at entry %" PRIu16,
ptr - cd_ptr, cd_length, i);
return -1;
}
}
ALOGV("+++ zip good scan %" PRIu16 " entries", num_entries);
return 0;
}
static int32_t OpenArchiveInternal(ZipArchive* archive,
const char* debug_file_name) {
int32_t result = -1;
if ((result = MapCentralDirectory(debug_file_name, archive)) != 0) {
return result;
}
if ((result = ParseZipArchive(archive))) {
return result;
}
return 0;
}
int32_t OpenArchiveFd(int fd, const char* debug_file_name,
ZipArchiveHandle* handle, bool assume_ownership) {
ZipArchive* archive = new ZipArchive(fd, assume_ownership);
*handle = archive;
return OpenArchiveInternal(archive, debug_file_name);
}
int32_t OpenArchive(const char* fileName, ZipArchiveHandle* handle) {
const int fd = open(fileName, O_RDONLY | O_BINARY, 0);
ZipArchive* archive = new ZipArchive(fd, true);
*handle = archive;
if (fd < 0) {
ALOGW("Unable to open '%s': %s", fileName, strerror(errno));
return kIoError;
}
return OpenArchiveInternal(archive, fileName);
}
int32_t OpenArchiveFromMemory(void* address, size_t length, const char* debug_file_name,
ZipArchiveHandle *handle) {
ZipArchive* archive = new ZipArchive(address, length);
*handle = archive;
return OpenArchiveInternal(archive, debug_file_name);
}
/*
* Close a ZipArchive, closing the file and freeing the contents.
*/
void CloseArchive(ZipArchiveHandle handle) {
ZipArchive* archive = reinterpret_cast<ZipArchive*>(handle);
ALOGV("Closing archive %p", archive);
delete archive;
}
static int32_t UpdateEntryFromDataDescriptor(MappedZipFile& mapped_zip,
ZipEntry *entry) {
uint8_t ddBuf[sizeof(DataDescriptor) + sizeof(DataDescriptor::kOptSignature)];
if (!mapped_zip.ReadData(ddBuf, sizeof(ddBuf))) {
return kIoError;
}
const uint32_t ddSignature = *(reinterpret_cast<const uint32_t*>(ddBuf));
const uint16_t offset = (ddSignature == DataDescriptor::kOptSignature) ? 4 : 0;
const DataDescriptor* descriptor = reinterpret_cast<const DataDescriptor*>(ddBuf + offset);
entry->crc32 = descriptor->crc32;
entry->compressed_length = descriptor->compressed_size;
entry->uncompressed_length = descriptor->uncompressed_size;
return 0;
}
static int32_t FindEntry(const ZipArchive* archive, const int ent,
ZipEntry* data) {
const uint16_t nameLen = archive->hash_table[ent].name_length;
// Recover the start of the central directory entry from the filename
// pointer. The filename is the first entry past the fixed-size data,
// so we can just subtract back from that.
const uint8_t* ptr = archive->hash_table[ent].name;
ptr -= sizeof(CentralDirectoryRecord);
// This is the base of our mmapped region, we have to sanity check that
// the name that's in the hash table is a pointer to a location within
// this mapped region.
const uint8_t* base_ptr = archive->central_directory.GetBasePtr();
if (ptr < base_ptr || ptr > base_ptr + archive->central_directory.GetMapLength()) {
ALOGW("Zip: Invalid entry pointer");
return kInvalidOffset;
}
const CentralDirectoryRecord *cdr =
reinterpret_cast<const CentralDirectoryRecord*>(ptr);
// The offset of the start of the central directory in the zipfile.
// We keep this lying around so that we can sanity check all our lengths
// and our per-file structures.
const off64_t cd_offset = archive->directory_offset;
// Fill out the compression method, modification time, crc32
// and other interesting attributes from the central directory. These
// will later be compared against values from the local file header.
data->method = cdr->compression_method;
data->mod_time = cdr->last_mod_date << 16 | cdr->last_mod_time;
data->crc32 = cdr->crc32;
data->compressed_length = cdr->compressed_size;
data->uncompressed_length = cdr->uncompressed_size;
// Figure out the local header offset from the central directory. The
// actual file data will begin after the local header and the name /
// extra comments.
const off64_t local_header_offset = cdr->local_file_header_offset;
if (local_header_offset + static_cast<off64_t>(sizeof(LocalFileHeader)) >= cd_offset) {
ALOGW("Zip: bad local hdr offset in zip");
return kInvalidOffset;
}
uint8_t lfh_buf[sizeof(LocalFileHeader)];
if (!archive->mapped_zip.ReadAtOffset(lfh_buf, sizeof(lfh_buf), local_header_offset)) {
ALOGW("Zip: failed reading lfh name from offset %" PRId64,
static_cast<int64_t>(local_header_offset));
return kIoError;
}
const LocalFileHeader *lfh = reinterpret_cast<const LocalFileHeader*>(lfh_buf);
if (lfh->lfh_signature != LocalFileHeader::kSignature) {
ALOGW("Zip: didn't find signature at start of lfh, offset=%" PRId64,
static_cast<int64_t>(local_header_offset));
return kInvalidOffset;
}
// Paranoia: Match the values specified in the local file header
// to those specified in the central directory.
// Verify that the central directory and local file header agree on the use of a trailing
// Data Descriptor.
if ((lfh->gpb_flags & kGPBDDFlagMask) != (cdr->gpb_flags & kGPBDDFlagMask)) {
ALOGW("Zip: gpb flag mismatch. expected {%04" PRIx16 "}, was {%04" PRIx16 "}",
cdr->gpb_flags, lfh->gpb_flags);
return kInconsistentInformation;
}
// If there is no trailing data descriptor, verify that the central directory and local file
// header agree on the crc, compressed, and uncompressed sizes of the entry.
if ((lfh->gpb_flags & kGPBDDFlagMask) == 0) {
data->has_data_descriptor = 0;
if (data->compressed_length != lfh->compressed_size
|| data->uncompressed_length != lfh->uncompressed_size
|| data->crc32 != lfh->crc32) {
ALOGW("Zip: size/crc32 mismatch. expected {%" PRIu32 ", %" PRIu32
", %" PRIx32 "}, was {%" PRIu32 ", %" PRIu32 ", %" PRIx32 "}",
data->compressed_length, data->uncompressed_length, data->crc32,
lfh->compressed_size, lfh->uncompressed_size, lfh->crc32);
return kInconsistentInformation;
}
} else {
data->has_data_descriptor = 1;
}
// Check that the local file header name matches the declared
// name in the central directory.
if (lfh->file_name_length == nameLen) {
const off64_t name_offset = local_header_offset + sizeof(LocalFileHeader);
if (name_offset + lfh->file_name_length > cd_offset) {
ALOGW("Zip: Invalid declared length");
return kInvalidOffset;
}
std::vector<uint8_t> name_buf(nameLen);
if (!archive->mapped_zip.ReadAtOffset(name_buf.data(), nameLen, name_offset)) {
ALOGW("Zip: failed reading lfh name from offset %" PRId64, static_cast<int64_t>(name_offset));
return kIoError;
}
if (memcmp(archive->hash_table[ent].name, name_buf.data(), nameLen)) {
return kInconsistentInformation;
}
} else {
ALOGW("Zip: lfh name did not match central directory.");
return kInconsistentInformation;
}
const off64_t data_offset = local_header_offset + sizeof(LocalFileHeader)
+ lfh->file_name_length + lfh->extra_field_length;
if (data_offset > cd_offset) {
ALOGW("Zip: bad data offset %" PRId64 " in zip", static_cast<int64_t>(data_offset));
return kInvalidOffset;
}
if (static_cast<off64_t>(data_offset + data->compressed_length) > cd_offset) {
ALOGW("Zip: bad compressed length in zip (%" PRId64 " + %" PRIu32 " > %" PRId64 ")",
static_cast<int64_t>(data_offset), data->compressed_length, static_cast<int64_t>(cd_offset));
return kInvalidOffset;
}
if (data->method == kCompressStored &&
static_cast<off64_t>(data_offset + data->uncompressed_length) > cd_offset) {
ALOGW("Zip: bad uncompressed length in zip (%" PRId64 " + %" PRIu32 " > %" PRId64 ")",
static_cast<int64_t>(data_offset), data->uncompressed_length,
static_cast<int64_t>(cd_offset));
return kInvalidOffset;
}
data->offset = data_offset;
return 0;
}
struct IterationHandle {
uint32_t position;
// We're not using vector here because this code is used in the Windows SDK
// where the STL is not available.
ZipString prefix;
ZipString suffix;
ZipArchive* archive;
IterationHandle(const ZipString* in_prefix,
const ZipString* in_suffix) {
if (in_prefix) {
uint8_t* name_copy = new uint8_t[in_prefix->name_length];
memcpy(name_copy, in_prefix->name, in_prefix->name_length);
prefix.name = name_copy;
prefix.name_length = in_prefix->name_length;
} else {
prefix.name = NULL;
prefix.name_length = 0;
}
if (in_suffix) {
uint8_t* name_copy = new uint8_t[in_suffix->name_length];
memcpy(name_copy, in_suffix->name, in_suffix->name_length);
suffix.name = name_copy;
suffix.name_length = in_suffix->name_length;
} else {
suffix.name = NULL;
suffix.name_length = 0;
}
}
~IterationHandle() {
delete[] prefix.name;
delete[] suffix.name;
}
};
int32_t StartIteration(ZipArchiveHandle handle, void** cookie_ptr,
const ZipString* optional_prefix,
const ZipString* optional_suffix) {
ZipArchive* archive = reinterpret_cast<ZipArchive*>(handle);
if (archive == NULL || archive->hash_table == NULL) {
ALOGW("Zip: Invalid ZipArchiveHandle");
return kInvalidHandle;
}
IterationHandle* cookie = new IterationHandle(optional_prefix, optional_suffix);
cookie->position = 0;
cookie->archive = archive;
*cookie_ptr = cookie ;
return 0;
}
void EndIteration(void* cookie) {
delete reinterpret_cast<IterationHandle*>(cookie);
}
int32_t FindEntry(const ZipArchiveHandle handle, const ZipString& entryName,
ZipEntry* data) {
const ZipArchive* archive = reinterpret_cast<ZipArchive*>(handle);
if (entryName.name_length == 0) {
ALOGW("Zip: Invalid filename %.*s", entryName.name_length, entryName.name);
return kInvalidEntryName;
}
const int64_t ent = EntryToIndex(archive->hash_table,
archive->hash_table_size, entryName);
if (ent < 0) {
ALOGV("Zip: Could not find entry %.*s", entryName.name_length, entryName.name);
return ent;
}
return FindEntry(archive, ent, data);
}
int32_t Next(void* cookie, ZipEntry* data, ZipString* name) {
IterationHandle* handle = reinterpret_cast<IterationHandle*>(cookie);
if (handle == NULL) {
return kInvalidHandle;
}
ZipArchive* archive = handle->archive;
if (archive == NULL || archive->hash_table == NULL) {
ALOGW("Zip: Invalid ZipArchiveHandle");
return kInvalidHandle;
}
const uint32_t currentOffset = handle->position;
const uint32_t hash_table_length = archive->hash_table_size;
const ZipString* hash_table = archive->hash_table;
for (uint32_t i = currentOffset; i < hash_table_length; ++i) {
if (hash_table[i].name != NULL &&
(handle->prefix.name_length == 0 ||
hash_table[i].StartsWith(handle->prefix)) &&
(handle->suffix.name_length == 0 ||
hash_table[i].EndsWith(handle->suffix))) {
handle->position = (i + 1);
const int error = FindEntry(archive, i, data);
if (!error) {
name->name = hash_table[i].name;
name->name_length = hash_table[i].name_length;
}
return error;
}
}
handle->position = 0;
return kIterationEnd;
}
class Writer {
public:
virtual bool Append(uint8_t* buf, size_t buf_size) = 0;
virtual ~Writer() {}
protected:
Writer() = default;
private:
DISALLOW_COPY_AND_ASSIGN(Writer);
};
// A Writer that writes data to a fixed size memory region.
// The size of the memory region must be equal to the total size of
// the data appended to it.
class MemoryWriter : public Writer {
public:
MemoryWriter(uint8_t* buf, size_t size) : Writer(),
buf_(buf), size_(size), bytes_written_(0) {
}
virtual bool Append(uint8_t* buf, size_t buf_size) override {
if (bytes_written_ + buf_size > size_) {
ALOGW("Zip: Unexpected size " ZD " (declared) vs " ZD " (actual)",
size_, bytes_written_ + buf_size);
return false;
}
memcpy(buf_ + bytes_written_, buf, buf_size);
bytes_written_ += buf_size;
return true;
}
private:
uint8_t* const buf_;
const size_t size_;
size_t bytes_written_;
};
// A Writer that appends data to a file |fd| at its current position.
// The file will be truncated to the end of the written data.
class FileWriter : public Writer {
public:
// Creates a FileWriter for |fd| and prepare to write |entry| to it,
// guaranteeing that the file descriptor is valid and that there's enough
// space on the volume to write out the entry completely and that the file
// is truncated to the correct length (no truncation if |fd| references a
// block device).
//
// Returns a valid FileWriter on success, |nullptr| if an error occurred.
static std::unique_ptr<FileWriter> Create(int fd, const ZipEntry* entry) {
const uint32_t declared_length = entry->uncompressed_length;
const off64_t current_offset = lseek64(fd, 0, SEEK_CUR);
if (current_offset == -1) {
ALOGW("Zip: unable to seek to current location on fd %d: %s", fd, strerror(errno));
return nullptr;
}
int result = 0;
#if defined(__linux__)
if (declared_length > 0) {
// Make sure we have enough space on the volume to extract the compressed
// entry. Note that the call to ftruncate below will change the file size but
// will not allocate space on disk and this call to fallocate will not
// change the file size.
// Note: fallocate is only supported by the following filesystems -
// btrfs, ext4, ocfs2, and xfs. Therefore fallocate might fail with
// EOPNOTSUPP error when issued in other filesystems.
// Hence, check for the return error code before concluding that the
// disk does not have enough space.
result = TEMP_FAILURE_RETRY(fallocate(fd, 0, current_offset, declared_length));
if (result == -1 && errno == ENOSPC) {
ALOGW("Zip: unable to allocate %" PRId64 " bytes at offset %" PRId64 " : %s",
static_cast<int64_t>(declared_length), static_cast<int64_t>(current_offset),
strerror(errno));
return std::unique_ptr<FileWriter>(nullptr);
}
}
#endif // __linux__
struct stat sb;
if (fstat(fd, &sb) == -1) {
ALOGW("Zip: unable to fstat file: %s", strerror(errno));
return std::unique_ptr<FileWriter>(nullptr);
}
// Block device doesn't support ftruncate(2).
if (!S_ISBLK(sb.st_mode)) {
result = TEMP_FAILURE_RETRY(ftruncate(fd, declared_length + current_offset));
if (result == -1) {
ALOGW("Zip: unable to truncate file to %" PRId64 ": %s",
static_cast<int64_t>(declared_length + current_offset), strerror(errno));
return std::unique_ptr<FileWriter>(nullptr);
}
}
return std::unique_ptr<FileWriter>(new FileWriter(fd, declared_length));
}
virtual bool Append(uint8_t* buf, size_t buf_size) override {
if (total_bytes_written_ + buf_size > declared_length_) {
ALOGW("Zip: Unexpected size " ZD " (declared) vs " ZD " (actual)",
declared_length_, total_bytes_written_ + buf_size);
return false;
}
const bool result = android::base::WriteFully(fd_, buf, buf_size);
if (result) {
total_bytes_written_ += buf_size;
} else {
ALOGW("Zip: unable to write " ZD " bytes to file; %s", buf_size, strerror(errno));
}
return result;
}
private:
FileWriter(const int fd, const size_t declared_length) :
Writer(),
fd_(fd),
declared_length_(declared_length),
total_bytes_written_(0) {
}
const int fd_;
const size_t declared_length_;
size_t total_bytes_written_;
};
// This method is using libz macros with old-style-casts
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wold-style-cast"
static inline int zlib_inflateInit2(z_stream* stream, int window_bits) {
return inflateInit2(stream, window_bits);
}
#pragma GCC diagnostic pop
static int32_t InflateEntryToWriter(MappedZipFile& mapped_zip, const ZipEntry* entry,
Writer* writer, uint64_t* crc_out) {
const size_t kBufSize = 32768;
std::vector<uint8_t> read_buf(kBufSize);
std::vector<uint8_t> write_buf(kBufSize);
z_stream zstream;
int zerr;
/*
* Initialize the zlib stream struct.
*/
memset(&zstream, 0, sizeof(zstream));
zstream.zalloc = Z_NULL;
zstream.zfree = Z_NULL;
zstream.opaque = Z_NULL;
zstream.next_in = NULL;
zstream.avail_in = 0;
zstream.next_out = &write_buf[0];
zstream.avail_out = kBufSize;
zstream.data_type = Z_UNKNOWN;
/*
* Use the undocumented "negative window bits" feature to tell zlib
* that there's no zlib header waiting for it.
*/
zerr = zlib_inflateInit2(&zstream, -MAX_WBITS);
if (zerr != Z_OK) {
if (zerr == Z_VERSION_ERROR) {
ALOGE("Installed zlib is not compatible with linked version (%s)",
ZLIB_VERSION);
} else {
ALOGW("Call to inflateInit2 failed (zerr=%d)", zerr);
}
return kZlibError;
}
auto zstream_deleter = [](z_stream* stream) {
inflateEnd(stream); /* free up any allocated structures */
};
std::unique_ptr<z_stream, decltype(zstream_deleter)> zstream_guard(&zstream, zstream_deleter);
const uint32_t uncompressed_length = entry->uncompressed_length;
uint32_t compressed_length = entry->compressed_length;
do {
/* read as much as we can */
if (zstream.avail_in == 0) {
const size_t getSize = (compressed_length > kBufSize) ? kBufSize : compressed_length;
if (!mapped_zip.ReadData(read_buf.data(), getSize)) {
ALOGW("Zip: inflate read failed, getSize = %zu: %s", getSize, strerror(errno));
return kIoError;
}
compressed_length -= getSize;
zstream.next_in = &read_buf[0];
zstream.avail_in = getSize;
}
/* uncompress the data */
zerr = inflate(&zstream, Z_NO_FLUSH);
if (zerr != Z_OK && zerr != Z_STREAM_END) {
ALOGW("Zip: inflate zerr=%d (nIn=%p aIn=%u nOut=%p aOut=%u)",
zerr, zstream.next_in, zstream.avail_in,
zstream.next_out, zstream.avail_out);
return kZlibError;
}
/* write when we're full or when we're done */
if (zstream.avail_out == 0 ||
(zerr == Z_STREAM_END && zstream.avail_out != kBufSize)) {
const size_t write_size = zstream.next_out - &write_buf[0];
if (!writer->Append(&write_buf[0], write_size)) {
// The file might have declared a bogus length.
return kInconsistentInformation;
}
zstream.next_out = &write_buf[0];
zstream.avail_out = kBufSize;
}
} while (zerr == Z_OK);
assert(zerr == Z_STREAM_END); /* other errors should've been caught */
// stream.adler holds the crc32 value for such streams.
*crc_out = zstream.adler;
if (zstream.total_out != uncompressed_length || compressed_length != 0) {
ALOGW("Zip: size mismatch on inflated file (%lu vs %" PRIu32 ")",
zstream.total_out, uncompressed_length);
return kInconsistentInformation;
}
return 0;
}
static int32_t CopyEntryToWriter(MappedZipFile& mapped_zip, const ZipEntry* entry, Writer* writer,
uint64_t *crc_out) {
static const uint32_t kBufSize = 32768;
std::vector<uint8_t> buf(kBufSize);
const uint32_t length = entry->uncompressed_length;
uint32_t count = 0;
uint64_t crc = 0;
while (count < length) {
uint32_t remaining = length - count;
// Safe conversion because kBufSize is narrow enough for a 32 bit signed
// value.
const size_t block_size = (remaining > kBufSize) ? kBufSize : remaining;
if (!mapped_zip.ReadData(buf.data(), block_size)) {
ALOGW("CopyFileToFile: copy read failed, block_size = %zu: %s", block_size, strerror(errno));
return kIoError;
}
if (!writer->Append(&buf[0], block_size)) {
return kIoError;
}
crc = crc32(crc, &buf[0], block_size);
count += block_size;
}
*crc_out = crc;
return 0;
}
int32_t ExtractToWriter(ZipArchiveHandle handle,
ZipEntry* entry, Writer* writer) {
ZipArchive* archive = reinterpret_cast<ZipArchive*>(handle);
const uint16_t method = entry->method;
off64_t data_offset = entry->offset;
if (!archive->mapped_zip.SeekToOffset(data_offset)) {
ALOGW("Zip: lseek to data at %" PRId64 " failed", static_cast<int64_t>(data_offset));
return kIoError;
}
// this should default to kUnknownCompressionMethod.
int32_t return_value = -1;
uint64_t crc = 0;
if (method == kCompressStored) {
return_value = CopyEntryToWriter(archive->mapped_zip, entry, writer, &crc);
} else if (method == kCompressDeflated) {
return_value = InflateEntryToWriter(archive->mapped_zip, entry, writer, &crc);
}
if (!return_value && entry->has_data_descriptor) {
return_value = UpdateEntryFromDataDescriptor(archive->mapped_zip, entry);
if (return_value) {
return return_value;
}
}
// TODO: Fix this check by passing the right flags to inflate2 so that
// it calculates the CRC for us.
if (entry->crc32 != crc && false) {
ALOGW("Zip: crc mismatch: expected %" PRIu32 ", was %" PRIu64, entry->crc32, crc);
return kInconsistentInformation;
}
return return_value;
}
int32_t ExtractToMemory(ZipArchiveHandle handle, ZipEntry* entry,
uint8_t* begin, uint32_t size) {
std::unique_ptr<Writer> writer(new MemoryWriter(begin, size));
return ExtractToWriter(handle, entry, writer.get());
}
int32_t ExtractEntryToFile(ZipArchiveHandle handle,
ZipEntry* entry, int fd) {
std::unique_ptr<Writer> writer(FileWriter::Create(fd, entry));
if (writer.get() == nullptr) {
return kIoError;
}
return ExtractToWriter(handle, entry, writer.get());
}
const char* ErrorCodeString(int32_t error_code) {
if (error_code > kErrorMessageLowerBound && error_code < kErrorMessageUpperBound) {
return kErrorMessages[error_code * -1];
}
return kErrorMessages[0];
}
int GetFileDescriptor(const ZipArchiveHandle handle) {
return reinterpret_cast<ZipArchive*>(handle)->mapped_zip.GetFileDescriptor();
}
ZipString::ZipString(const char* entry_name)
: name(reinterpret_cast<const uint8_t*>(entry_name)) {
size_t len = strlen(entry_name);
CHECK_LE(len, static_cast<size_t>(UINT16_MAX));
name_length = static_cast<uint16_t>(len);
}
#if !defined(_WIN32)
class ProcessWriter : public Writer {
public:
ProcessWriter(ProcessZipEntryFunction func, void* cookie) : Writer(),
proc_function_(func),
cookie_(cookie) {
}
virtual bool Append(uint8_t* buf, size_t buf_size) override {
return proc_function_(buf, buf_size, cookie_);
}
private:
ProcessZipEntryFunction proc_function_;
void* cookie_;
};
int32_t ProcessZipEntryContents(ZipArchiveHandle handle, ZipEntry* entry,
ProcessZipEntryFunction func, void* cookie) {
ProcessWriter writer(func, cookie);
return ExtractToWriter(handle, entry, &writer);
}
#endif //!defined(_WIN32)
int MappedZipFile::GetFileDescriptor() const {
if (!has_fd_) {
ALOGW("Zip: MappedZipFile doesn't have a file descriptor.");
return -1;
}
return fd_;
}
void* MappedZipFile::GetBasePtr() const {
if (has_fd_) {
ALOGW("Zip: MappedZipFile doesn't have a base pointer.");
return nullptr;
}
return base_ptr_;
}
off64_t MappedZipFile::GetFileLength() const {
if (has_fd_) {
off64_t result = lseek64(fd_, 0, SEEK_END);
if (result == -1) {
ALOGE("Zip: lseek on fd %d failed: %s", fd_, strerror(errno));
}
return result;
} else {
if (base_ptr_ == nullptr) {
ALOGE("Zip: invalid file map\n");
return -1;
}
return static_cast<off64_t>(data_length_);
}
}
bool MappedZipFile::SeekToOffset(off64_t offset) {
if (has_fd_) {
if (lseek64(fd_, offset, SEEK_SET) != offset) {
ALOGE("Zip: lseek to %" PRId64 " failed: %s\n", offset, strerror(errno));
return false;
}
return true;
} else {
if (offset < 0 || offset > static_cast<off64_t>(data_length_)) {
ALOGE("Zip: invalid offset: %" PRId64 ", data length: %" PRId64 "\n" , offset,
data_length_);
return false;
}
read_pos_ = offset;
return true;
}
}
bool MappedZipFile::ReadData(uint8_t* buffer, size_t read_amount) {
if (has_fd_) {
if(!android::base::ReadFully(fd_, buffer, read_amount)) {
ALOGE("Zip: read from %d failed\n", fd_);
return false;
}
} else {
memcpy(buffer, static_cast<uint8_t*>(base_ptr_) + read_pos_, read_amount);
read_pos_ += read_amount;
}
return true;
}
// Attempts to read |len| bytes into |buf| at offset |off|.
bool MappedZipFile::ReadAtOffset(uint8_t* buf, size_t len, off64_t off) {
#if !defined(_WIN32)
if (has_fd_) {
if (static_cast<size_t>(TEMP_FAILURE_RETRY(pread64(fd_, buf, len, off))) != len) {
ALOGE("Zip: failed to read at offset %" PRId64 "\n", off);
return false;
}
return true;
}
#endif
if (!SeekToOffset(off)) {
return false;
}
return ReadData(buf, len);
}
void CentralDirectory::Initialize(void* map_base_ptr, off64_t cd_start_offset, size_t cd_size) {
base_ptr_ = static_cast<uint8_t*>(map_base_ptr) + cd_start_offset;
length_ = cd_size;
}
bool ZipArchive::InitializeCentralDirectory(const char* debug_file_name, off64_t cd_start_offset,
size_t cd_size) {
if (mapped_zip.HasFd()) {
if (!directory_map->create(debug_file_name, mapped_zip.GetFileDescriptor(),
cd_start_offset, cd_size, true /* read only */)) {
return false;
}
CHECK_EQ(directory_map->getDataLength(), cd_size);
central_directory.Initialize(directory_map->getDataPtr(), 0/*offset*/, cd_size);
} else {
if (mapped_zip.GetBasePtr() == nullptr) {
ALOGE("Zip: Failed to map central directory, bad mapped_zip base pointer\n");
return false;
}
if (static_cast<off64_t>(cd_start_offset) + static_cast<off64_t>(cd_size) >
mapped_zip.GetFileLength()) {
ALOGE("Zip: Failed to map central directory, offset exceeds mapped memory region ("
"start_offset %" PRId64 ", cd_size %zu, mapped_region_size %" PRId64 ")",
static_cast<int64_t>(cd_start_offset), cd_size, mapped_zip.GetFileLength());
return false;
}
central_directory.Initialize(mapped_zip.GetBasePtr(), cd_start_offset, cd_size);
}
return true;
}