Magisk/native/jni/core/cert.cpp
2022-06-19 00:43:38 -07:00

209 lines
6.5 KiB
C++

#include <base.hpp>
using namespace std;
#define APK_SIGNING_BLOCK_MAGIC "APK Sig Block 42"
#define SIGNATURE_SCHEME_V2_MAGIC 0x7109871a
#define EOCD_MAGIC 0x6054b50
// Top-level block container
struct signing_block {
uint64_t block_sz;
struct id_value_pair {
uint64_t len;
struct /* v2_signature */ {
uint32_t id;
uint8_t value[0]; // size = (len - 4)
};
} id_value_pair_sequence[0];
uint64_t block_sz_; // *MUST* be same as block_sz
char magic[16]; // "APK Sig Block 42"
};
struct len_prefixed {
uint32_t len;
};
// Generic length prefixed raw data
struct len_prefixed_value : public len_prefixed {
uint8_t value[0];
};
// V2 Signature Block
struct v2_signature {
uint32_t id; // 0x7109871a
uint32_t signer_sequence_len;
struct signer : public len_prefixed {
struct signed_data : public len_prefixed {
uint32_t digest_sequence_len;
struct : public len_prefixed {
uint32_t algorithm;
len_prefixed_value digest;
} digest_sequence[0];
uint32_t certificate_sequence_len;
len_prefixed_value certificate_sequence[0];
uint32_t attribute_sequence_len;
struct attribute : public len_prefixed {
uint32_t id;
uint8_t value[0]; // size = (len - 4)
} attribute_sequence[0];
} signed_data;
uint32_t signature_sequence_len;
struct : public len_prefixed {
uint32_t id;
len_prefixed_value signature;
} signature_sequence[0];
len_prefixed_value public_key;
} signer_sequence[0];
};
// End of central directory record
struct EOCD {
uint32_t magic; // 0x6054b50
uint8_t pad[8]; // 8 bytes of irrelevant data
uint32_t central_dir_sz; // size of central directory
uint32_t central_dir_off; // offset of central directory
uint16_t comment_sz; // size of comment
char comment[0];
} __attribute__((packed));
/*
* A v2/v3 signed APK has the format as following
*
* +---------------+
* | zip content |
* +---------------+
* | signing block |
* +---------------+
* | central dir |
* +---------------+
* | EOCD |
* +---------------+
*
* Scan from end of file to find EOCD, and figure our way back to the
* offset of the signing block. Next, directly extract the certificate
* from the v2 signature block.
*
* All structures above are mostly just for documentation purpose.
*
* This method extracts the first certificate of the first signer
* within the APK v2 signature block.
*/
string read_certificate(int fd, int version) {
uint32_t u32;
uint64_t u64;
// Find EOCD
for (int i = 0;; i++) {
// i is the absolute offset to end of file
uint16_t comment_sz = 0;
xlseek(fd, -static_cast<off_t>(sizeof(comment_sz)) - i, SEEK_END);
xxread(fd, &comment_sz, sizeof(comment_sz));
if (comment_sz == i) {
// Double check if we actually found the structure
xlseek(fd, -static_cast<off_t>(sizeof(EOCD)), SEEK_CUR);
uint32_t magic = 0;
xxread(fd, &magic, sizeof(magic));
if (magic == EOCD_MAGIC) {
break;
}
}
if (i == 0xffff) {
// Comments cannot be longer than 0xffff (overflow), abort
LOGE("cert: invalid APK format\n");
return {};
}
}
// We are now at EOCD + sizeof(magic)
// Seek and read central_dir_off to find start of central directory
uint32_t central_dir_off = 0;
{
constexpr off_t off = offsetof(EOCD, central_dir_off) - sizeof(EOCD::magic);
xlseek(fd, off, SEEK_CUR);
}
xxread(fd, &central_dir_off, sizeof(central_dir_off));
// Parse APK comment to get version code
if (version >= 0) {
xlseek(fd, sizeof(EOCD::comment_sz), SEEK_CUR);
FILE *fp = fdopen(fd, "r"); // DO NOT close this file pointer
int apk_ver = -1;
parse_prop_file(fp, [&](string_view key, string_view value) -> bool {
if (key == "versionCode") {
apk_ver = parse_int(value);
return false;
}
return true;
});
if (version > apk_ver) {
// Enforce the magisk app to always be newer than magiskd
LOGE("cert: APK version too low\n");
return {};
}
}
// Next, find the start of the APK signing block
{
constexpr int off = sizeof(signing_block::block_sz_) + sizeof(signing_block::magic);
xlseek(fd, (off_t) (central_dir_off - off), SEEK_SET);
}
xxread(fd, &u64, sizeof(u64)); // u64 = block_sz_
char magic[sizeof(signing_block::magic)] = {0};
xxread(fd, magic, sizeof(magic));
if (memcmp(magic, APK_SIGNING_BLOCK_MAGIC, sizeof(magic)) != 0) {
// Invalid signing block magic, abort
LOGE("cert: invalid signing block magic\n");
return {};
}
uint64_t signing_blk_sz = 0;
xlseek(fd, -static_cast<off_t>(u64 + sizeof(signing_blk_sz)), SEEK_CUR);
xxread(fd, &signing_blk_sz, sizeof(signing_blk_sz));
if (signing_blk_sz != u64) {
// block_sz != block_sz_, invalid signing block format, abort
LOGE("cert: invalid signing block format\n");
return {};
}
// Finally, we are now at the beginning of the id-value pair sequence
for (;;) {
xxread(fd, &u64, sizeof(u64)); // id-value pair length
if (u64 == signing_blk_sz) {
// Outside of the id-value pair sequence; actually reading block_sz_
break;
}
uint32_t id;
xxread(fd, &id, sizeof(id));
if (id == SIGNATURE_SCHEME_V2_MAGIC) {
// Skip [signer sequence length] + [1st signer length] + [signed data length]
xlseek(fd, sizeof(uint32_t) * 3, SEEK_CUR);
xxread(fd, &u32, sizeof(u32)); // digest sequence length
xlseek(fd, u32, SEEK_CUR); // skip all digests
xlseek(fd, sizeof(uint32_t), SEEK_CUR); // cert sequence length
xxread(fd, &u32, sizeof(u32)); // 1st cert length
string cert;
cert.resize(u32);
xxread(fd, cert.data(), u32);
return cert;
} else {
// Skip this id-value pair
xlseek(fd, u64 - sizeof(id), SEEK_CUR);
}
}
LOGE("cert: cannot find certificate\n");
return {};
}