wiiqt/WiiQt/blocks0to7.cpp

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#include "blocks0to7.h"
#include "tools.h"
#include "tiktmd.h"
int check_cert_chain( const QByteArray data );
enum
{
ERROR_SUCCESS = 0,
ERROR_SIG_TYPE,
ERROR_SUB_TYPE,
ERROR_RSA_FAKESIGNED,
ERROR_RSA_HASH,
ERROR_RSA_TYPE_UNKNOWN,
ERROR_RSA_TYPE_MISMATCH,
ERROR_CERT_NOT_FOUND,
ERROR_COUNT
};
Blocks0to7::Blocks0to7( QList<QByteArray>blocks )
{
_ok = false;
if( !blocks.isEmpty() )
SetBlocks( blocks );
}
bool Blocks0to7::SetBlocks( QList<QByteArray>blocks )
{
_ok = false;
this->blocks.clear();
boot2Infos.clear();
quint16 cnt = blocks.size();
if( cnt != 8 )
return false;
for( quint16 i = 0; i < cnt; i++ )
{
if( blocks.at( i ).size() != 0x20000 )
{
qWarning() << "Blocks0to7::SetBlocks -> block" << i << "is" << hex << blocks.at( i ).size() << "bytes";
return false;
}
}
this->blocks = blocks;
_ok = true;
return true;
}
quint8 Blocks0to7::Boot1Version()
{
if( blocks.size() != 8 )
return BOOT_1_UNK;
QByteArray hash = GetSha1( blocks.at( 0 ) );
if( hash == QByteArray( "\x4a\x7c\x6f\x30\x38\xde\xea\x7a\x07\xd3\x32\x32\x02\x4b\xe9\x5a\xfb\x56\xbf\x65" ) )
return BOOT_1_A;
if( hash == QByteArray( "\x2c\xdd\x5a\xff\xd2\xe7\x8c\x53\x76\x16\xa1\x19\xa7\xa2\xe1\xc5\x68\xe9\x1f\x22" ) )
return BOOT_1_B;
if( hash == QByteArray( "\xf0\x1e\x8a\xca\x02\x9e\xe0\xcb\x52\x87\xf5\x05\x5d\xa1\xa0\xbe\xd2\xa5\x33\xfa" ) )
return BOOT_1_C;
if( hash == QByteArray( "\x8d\x9e\xcf\x2f\x8f\x98\xa3\xc1\x07\xf1\xe5\xe3\x6f\xf2\x4d\x57\x7e\xac\x36\x08" ) )
return BOOT_1_D; //displayed as "boot1?" in ceilingcat
return BOOT_1_UNK;
}
//really ugly thing to get the different versions of boot2.
//this doesnt take into account the possibility that boot2 is bigger and takes up more than 2 blocks
//there are 0x40 blocks in the blockmap, but only 8 are used. maybe IOS has the authority to hijack the others if
//it runs out of room here. if that ever happns, this code will become quite wrong
QList<Boot2Info> Blocks0to7::Boot2Infos()
{
if( !boot2Infos.isEmpty() )
{
//qDebug() << "Blocks0to7::Boot2Infos() returning data from last time";
return boot2Infos;
}
QList< Boot2Info > ret;
if( blocks.size() != 8 )
return ret;
quint16 cnt = blocks.size();
if( cnt != 8 )
return ret;
//get all the blockmaps
quint16 newest = 0;
quint8 lbm[ 8 ];
for( quint8 i = 1; i < 8; i++ )
{
Boot2Info info = GetBlockMap( blocks.at( i ) );
if( info.state == BOOT_2_ERROR )//this block doesnt contain a decent blockmap
continue;
info.secondBlock = i; //this one is easy enough
//find the first block that belongs to this second one
if( i > 4 )//blocks are backwards
{
bool found = false;
for( quint8 j = 7; j > i; j++ )
{
if( info.blockMap[ j ] )//marked bad
continue;
if( ( ( j > i + 1 ) && !info.blockMap[ i + 1 ] )//probably a much cleaner way to write this
|| ( j == 6 && !info.blockMap[ 7 ] ) ) //but basically check for a couple stupid shit in the layout that really shouldnt ever happen
break;
info.firstBlock = j;
found = true;
break;
}
if( !found )
continue;
}
else//blocks are forwards
{
bool found = false;
for( quint8 j = 0; j < i; j++ )
{
if( info.blockMap[ j ] )//marked bad
continue;
info.firstBlock = j;
found = true;
break;
}
if( !found )
continue;
found = false;
//probably a much cleaner way to write this
//but basically check for a couple stupid shit in the layout that really shouldnt ever happen
for( quint8 j = info.firstBlock + 1; j < info.secondBlock && !found; j++ )
{
if( info.blockMap[ j ] )//marked bad
continue;
found = true;
}
if( found )//this means there is some other good block between the first block and this one that has the block map
continue;
}
//we made it this far, it means that so far we have a correct looking blockmap that points to this copy of boot2
if( info.generation > newest )
{
newest = info.generation;
for( quint8 j = 0; j < 8; j++ )
lbm[ j ] = info.blockMap[ j ];
}
ret << info;
}
//qDebug() << "newest blockmap" << QByteArray( (const char*)&lbm, 8 ).toHex();
cnt = ret.size();
bool foundBoot = false;
bool foundBackup = false;
for( quint8 i = 0; i < cnt; i++ )
{
ret[ i ] = CheckHashes( ret[ i ] );//check all the hashes and stuff
if( !foundBoot && !lbm[ ret.at( i ).firstBlock ] && !lbm[ ret.at( i ).secondBlock ] )
{
//qDebug() << "copy" << i << "is used when booting";
ret[ i ].state |= BOOT_2_USED_TO_BOOT;
//ret[ i ].usedToBoot = true;
foundBoot = true;
}
else if( lbm[ ret.at( i ).firstBlock ] || lbm[ ret.at( i ).secondBlock ] )
{
ret[ i ].state |= BOOT_2_MARKED_BAD;
}
}
for( quint8 i = ret.size(); !foundBackup && i > 0; i-- )
{
if( !lbm[ ret.at( i - 1 ).firstBlock ] && !lbm[ ret.at( i - 1 ).secondBlock ] && ret.at( i - 1 ).firstBlock > ret.at( i - 1 ).secondBlock )
{
//qDebug() << "copy" << i << "is used when booting from backup";
ret[ i - 1 ].state |= BOOT_2_BACKUP_COPY;
foundBackup = true;
if( !foundBoot )
ret[ i - 1 ].state |= BOOT_2_USED_TO_BOOT;
}
}
boot2Infos = ret;
return ret;
}
Boot2Info Blocks0to7::GetBlockMap( QByteArray block )
{
Boot2Info ret;
ret.state = BOOT_2_ERROR;
if( block.size() != 0x20000 )
return ret;
QByteArray first = block.mid( 0x1f800, 0x4c );
QByteArray second = block.mid( 0x1f84c, 0x4c );
QByteArray third = block.mid( 0x1f898, 0x4c );
QByteArray goodOne = QByteArray( "\x26\xF2\x9A\x40\x1E\xE6\x84\xCF" );
if( first.startsWith( goodOne ) && ( first == second || first == third ) )
goodOne = first;
else if( second.startsWith( goodOne ) && ( second == third ) )
goodOne = second;
else
return ret;
ret.generation = goodOne.mid( 8, 4 ).toHex().toInt( NULL, 16 );
for( quint8 i = 0; i < 8; i++ )
ret.blockMap[ i ] = goodOne.at( i + 12 );
ret.state = BOOT_2_TIK_SIG_OK; //just assign this for now. it will be corrected before this data leaves the class
return ret;
}
Boot2Info Blocks0to7::CheckHashes( Boot2Info info )
{
Boot2Info ret = info;
ret.state = BOOT_2_ERROR_PARSING;
QByteArray stuff = blocks.at( ret.firstBlock );
QBuffer b( &stuff );
b.open( QIODevice::ReadOnly );
quint32 headerSize;
quint32 dataOff;
quint32 certSize;
quint32 ticketSize;
quint32 tmdSize;
quint32 tmp;
b.read( (char*)&tmp, 4 );
headerSize = qFromBigEndian( tmp );
if( headerSize != 0x20 )
return ret;
b.read( (char*)&tmp, 4 );
dataOff = qFromBigEndian( tmp );
b.read( (char*)&tmp, 4 );
certSize = qFromBigEndian( tmp );
b.read( (char*)&tmp, 4 );
ticketSize = qFromBigEndian( tmp );
b.read( (char*)&tmp, 4 );
tmdSize = qFromBigEndian( tmp );
b.close();
QByteArray tikD = stuff.mid( headerSize + certSize, ticketSize );
QByteArray tmdD = stuff.mid( headerSize + certSize + ticketSize, tmdSize );
Tmd t( tmdD );
Ticket ticket( tikD );
if( t.Tid() != 0x100000001ull || ticket.Tid() != 0x100000001ull )
{
qWarning() << "Blocks0to7::CheckHashes -> bad TID";
return ret;
}
ret.state = 0;
int res = check_cert_chain( tikD );
switch( res )
{
default:
case ERROR_SIG_TYPE:
case ERROR_SUB_TYPE:
case ERROR_RSA_TYPE_UNKNOWN:
case ERROR_CERT_NOT_FOUND:
ret.state = BOOT_2_ERROR;
qWarning() << "check_cert_chain( tikD ):" << res;
return ret;
break;
case ERROR_RSA_TYPE_MISMATCH:
case ERROR_RSA_HASH:
ret.state = BOOT_2_BAD_SIGNATURE;
//qWarning() << "check_cert_chain( tikD ):" << res;
return ret;
break;
case ERROR_RSA_FAKESIGNED:
ret.state |= BOOT_2_TIK_FAKESIGNED;
break;
case ERROR_SUCCESS:
ret.state |= BOOT_2_TIK_SIG_OK;
break;
}
res = check_cert_chain( tmdD );
switch( res )
{
default:
case ERROR_SIG_TYPE:
case ERROR_SUB_TYPE:
case ERROR_RSA_TYPE_UNKNOWN:
case ERROR_CERT_NOT_FOUND:
ret.state = BOOT_2_ERROR;
//qWarning() << "check_cert_chain( tikD ):" << res;
return ret;
break;
case ERROR_RSA_TYPE_MISMATCH:
case ERROR_RSA_HASH:
ret.state = BOOT_2_BAD_SIGNATURE;
//qWarning() << "check_cert_chain( tikD ):" << res;
return ret;
break;
case ERROR_RSA_FAKESIGNED:
{
ret.state |= BOOT_2_TMD_FAKESIGNED;
if( tmdD.contains( "BM1.1" ) )
ret.version = BOOTMII_11;
else if( tmdD.contains( "BM1.3" ) )
ret.version = BOOTMII_13;
else
ret.version = BOOTMII_UNK;
}
break;
case ERROR_SUCCESS:
{
ret.state |= BOOT_2_TMD_SIG_OK;
ret.version = t.Version();
}
break;
}
//now decrypt boot2 and check the hash ( only checking 1 content because thats all there is )
stuff += blocks.at( ret.secondBlock );
AesSetKey( ticket.DecryptedKey() );
QByteArray decD = AesDecrypt( 0, stuff.mid( dataOff, RU( 0x40, t.Size( 0 ) ) ) );
decD.resize( t.Size( 0 ) );
QByteArray realHash = GetSha1( decD );
if( realHash != t.Hash( 0 ) )
ret.state |= BOOT_2_BAD_CONTENT_HASH;
return ret;
}
//theres probably a better place to put all this stuff. but until then, just put it here
#define BE32(a) (((a)[0] << 24)|((a)[1] << 16)|((a)[2] << 8)|(a)[3])
#define bn_zero(a,b) memset(a,0,b)
#define bn_copy(a,b,c) memcpy(a,b,c)
#define bn_compare(a,b,c) memcmp(a,b,c)
// calc a = a mod N, given n = size of a,N in bytes
static void bn_sub_modulus( quint8 *a, const quint8 *N, const quint32 n )
{
quint32 dig;
quint8 c = 0;
for( quint32 i = n - 1; i < n; i-- )
{
dig = N[ i ] + c;
c = ( a [ i ] < dig );
a[ i ] -= dig;
}
}
// calc d = (a + b) mod N, given n = size of d,a,b,N in bytes
static void bn_add( quint8 *d, const quint8 *a, const quint8 *b, const quint8 *N, const quint32 n )
{
quint32 i;
quint32 dig;
quint8 c = 0;
for( i = n - 1; i < n; i--)
{
dig = a[ i ] + b[ i ] + c;
c = ( dig >= 0x100 );
d[ i ] = dig;
}
if( c )
bn_sub_modulus( d, N, n );
if( bn_compare( d, N, n ) >= 0 )
bn_sub_modulus( d, N, n );
}
// calc d = (a * b) mod N, given n = size of d,a,b,N in bytes
static void bn_mul( quint8 *d, const quint8 *a, const quint8 *b, const quint8 *N, const quint32 n )
{
quint8 mask;
bn_zero( d, n );
for( quint32 i = 0; i < n; i++ )
for( mask = 0x80; mask != 0; mask >>= 1 )
{
bn_add( d, d, d, N, n );
if( ( a[ i ] & mask ) != 0 )
bn_add( d, d, b, N, n );
}
}
// calc d = (a ^ e) mod N, given n = size of d,a,N and en = size of e in bytes
static void bn_exp( quint8 *d, const quint8 *a, const quint8 *N, const quint32 n, const quint8 *e, const quint32 en )
{
quint8 t[ 512 ];
quint8 mask;
bn_zero( d, n );
d[ n-1 ] = 1;
for( quint32 i = 0; i < en; i++ )
for( mask = 0x80; mask != 0; mask >>= 1 )
{
bn_mul( t, d, d, N, n );
if( ( e [ i ] & mask ) != 0 )
bn_mul( d, t, a, N, n );
else
bn_copy( d, t, n );
}
}
static int get_sig_len( const quint8 *sig )
{
quint32 type;
type = BE32( sig );
switch( type - 0x10000 )
{
case 0:
return 0x240;
case 1:
return 0x140;
case 2:
return 0x80;
}
return -ERROR_SIG_TYPE;
}
static int get_sub_len( const quint8 *sub )
{
quint32 type;
type = BE32( sub + 0x40 );
switch( type )
{
case 0: return 0x2c0;
case 1: return 0x1c0;
case 2: return 0x100;
}
return -ERROR_SUB_TYPE;
}
static int check_rsa( QByteArray h, const quint8 *sig, const quint8 *key, const quint32 n )
{
quint8 correct[ 0x200 ], x[ 0x200 ];
static const quint8 ber[ 16 ] = { 0x00,0x30,0x21,0x30,0x09,0x06,0x05,0x2b,
0x0e,0x03,0x02,0x1a,0x05,0x00,0x04,0x14 };
correct[ 0 ] = 0;
correct[ 1 ] = 1;
memset( correct + 2, 0xff, n - 38 );
memcpy( correct + n - 36, ber, 16 );
memcpy( correct + n - 20, h.constData(), 20 );
bn_exp( x, sig, key, n, key + n, 4 );
//qDebug() << "Decrypted signature hash:" << QByteArray( (const char*)&x[ n-20 ], 20 ).toHex();
//qDebug() << " SHA1 hash:" << h.toHex();
if( memcmp( correct, x, n ) == 0 )
return 0;
if( strncmp( (char*)h.constData(), (char*) x + n - 20, 20 ) == 0 )
return ERROR_RSA_FAKESIGNED;
return ERROR_RSA_HASH;
}
static int check_hash( QByteArray h, const quint8 *sig, const quint8 *key )
{
quint32 type;
type = BE32( sig ) - 0x10000;
if( (qint32)type != BE32( key + 0x40 ) )
return ERROR_RSA_TYPE_MISMATCH;
if( type == 1 )
return check_rsa( h, sig + 4, key + 0x88, 0x100 );
return ERROR_RSA_TYPE_UNKNOWN;
}
static const quint8* find_cert_in_chain( const quint8 *sub, const quint8 *cert, const quint32 cert_len, int *err )
{
char parent[ 64 ], *child;
int sig_len, sub_len;
const quint8 *p, *issuer;
strncpy( parent, (char*)sub, sizeof parent );
parent[ sizeof parent - 1 ] = 0;
child = strrchr( parent, '-' );
if( child )
*child++ = 0;
else
{
*parent = 0;
child = (char*)sub;
}
*err = -ERROR_CERT_NOT_FOUND;
for( p = cert; p < cert + cert_len; p += sig_len + sub_len )
{
sig_len = get_sig_len( p );
if( sig_len < 0 )
{
*err = sig_len;
break;
}
issuer = p + sig_len;
sub_len = get_sub_len( issuer );
if( sub_len < 0 )
{
*err = sub_len;
break;
}
if( strcmp( parent, (char*)issuer ) == 0 && strcmp( child, (char*)issuer + 0x44 ) == 0 )
return p;
}
return NULL;
}
int check_cert_chain( const QByteArray data )
{
int cert_err;
const quint8* key;
const quint8 *sig, *sub, *key_cert;
int sig_len, sub_len;
QByteArray h;
int ret;
const quint8 *certificates = certs_dat;
sig = (const quint8*)data.constData();
sig_len = get_sig_len( sig );
if( sig_len < 0 )
return -sig_len;
sub = (const quint8*)( data.data() + sig_len );
sub_len = data.size() - sig_len;
if( sub_len <= 0 )
return ERROR_SUB_TYPE;
for( ; ; )
{
//qDebug() << "Verifying using" << QString( (const char*) sub );
if( strcmp((char*)sub, "Root" ) == 0 )
{
key = root_dat;
h = GetSha1( QByteArray( (const char*)sub, sub_len ) );
if( BE32( sig ) != 0x10000 )
return ERROR_SIG_TYPE;
return check_rsa( h, sig + 4, key, 0x200 );
}
key_cert = find_cert_in_chain( sub, certificates, CERTS_DAT_SIZE, &cert_err );
if( key_cert )
cert_err = get_sig_len( key_cert );
if( cert_err < 0 )
return -cert_err;
key = key_cert + cert_err;
h = GetSha1( QByteArray( (const char*)sub, sub_len ) );
ret = check_hash( h, sig, key );
// remove this if statement if you don't want to check the whole chain
if( ret != ERROR_SUCCESS )
return ret;
sig = key_cert;
sig_len = get_sig_len( sig );
if( sig_len < 0 )
return -sig_len;
sub = sig + sig_len;
sub_len = get_sub_len( sub );
if( sub_len < 0 )
return -sub_len;
}
}