Difference between revisions of "SceSblGcAuthMgr"

SBL Game Card Auth Manager

Module

Libraries

Known NIDs

Data segment layout

SceSblGcAuthMgrDrmBBForDriver

command 0x1000B 0x11

Original PSP Kirk 0x11 service for 160bit ECC signature verification.

command 0x1000B 0x18

224bit version of PSP Kirk 0x11 service

command 0x1000B 0x21

command 0x1000B 0x22

command 0x1000B 0x4

Original PSP Kirk 4 service for encrypting data

command 0x1000B 0x4

Original PSP Kirk 4 service for encrypting data

command 0x1000B 0x4

Original PSP Kirk 4 service for encrypting data

command 0x1000B 0x4

Original PSP Kirk 4 service for encrypting data

command 0x1000B 0x7

Original PSP Kirk 7 service for decrypting data

command 0x1000B 0x7

Original PSP Kirk 7 service for decrypting data

command 0x1000B 0x7

Original PSP Kirk 7 service for decrypting data

command 0x1000B 0x4 0x7

Original PSP Kirk Enc and Dec

int unk_4FE89ADB(int unk0, int unk1, int unk2, int unk3, int arg_0);

clear_context

typedef struct ctx_48D7784E { //size is 0x28
   uint32_t unk_0;
   char unk_4[0x10];
   char unk_14[0x10];
   uint32_t unk_24;
}ctx_48D7784E;

int clear_context(ctx_48D7784E *ctx, int idx);

clear_context

typedef struct ctx_6E6D2B89 { //size is 0x18
   uint32_t unk_0;
   uint32_t unk_4;
   char unk_8[0x10];
} ctx_6E6D2B89;

int clear_context(ctx_6E6D2B89 *ctx);

enc_dec

Includes both AES and PSP Kirk 0x1000B 4 and 7.

int enc_dec(void* data, void* dec_rif_key, int unk2, void* unk3);

error

Returns error 0x808A040A.

get_5018_data

This function copies first 0x20 bytes of the buffer of size 0x34 to destination.

Buffer is obtained with KIRK command 0x20.

int get_5018_data(char* dest);

memcmp_safe_5018

Temp name was memcmp_5018_fast.

This function verifies that last 0x14 bytes of last response of size 0x34 from the game card (cmd56) are valid.

CMD56 response Buffer is obtained with KIRK command 0x20

For example it is called from SceAppMgr#sceAppMgrGameDataMount.

This is a timing safe memcmp. Xyz (talk) 10:02, 1 May 2017 (UTC)

int memcmp_safe_5018(char* in_data);

clear_sensitive_data

Clears some sensitive data.

Called after memcmp_safe_5018.

int clear_sensitive_data(int unk, int* value);

clear_sensitive_data_2

Clears sensitive data that is left after cmd56 custom initialization.

This includes data generated by Kirk services 0x1C, 0x1F, 0x20 and packet6.

Buffer offsets are 0x4BC4, 0x4FF8, 0x5018, 0x544C.

Called after initialize_sd_device.

int clear_sensitive_data_2();

SceSblGcAuthMgrAdhocBBForDriver

Present on FW 1.69. Not present on FWs >= 3.60.

sceSblGcAuthMgrAdhocBB224InitForDriver

sceSblGcAuthMgrAdhocBB224ShutdownForDriver

sceSblGcAuthMgrAdhocBB224GetKeysForDriver

sceSblGcAuthMgrAdhocBB224Auth1ForDriver

sceSblGcAuthMgrAdhocBB224Auth2ForDriver

sceSblGcAuthMgrAdhocBB224Auth3ForDriver

sceSblGcAuthMgrAdhocBB224Auth4ForDriver

sceSblGcAuthMgrAdhocBB224Auth5ForDriver

SceSblGcAuthMgrPcactForDriver

Present on 0.990-1.69. Not present on 3.60+.

sceSblGcAuthMgrPcactActivationForDriver

Calls get_aes_dec_key then SceNpDrm set_act_data.

typedef struct ScePcactUnkBuf { // size is 0x50 on FW 0.990
  short unk_0; // must be 0x211
  char mode;
  char reserved[0xD]; // must be zeroed
  char unk_10[0x40]; // might be keys generated from ConsoleId
} ScePcactUnkBuf;

typedef struct ScePcactActivationData { // size is 0x1090 on FW 0.990
  ScePcactUnkBuf unk_buf;
  char act_dat[0x1040];
} ScePcactActivationData;

int sceSblGcAuthMgrPcactActivationForDriver(const ScePcactActivationData *act_data, SceSize act_data_size);

sceSblGcAuthMgrPcactGetChallengeForDriver

Calls SceSblGcAuthMgrPcactForDriver_B7AE58B9.

// entropy (epassword) size is 0x20 bytes
// challenge size is 0x80 bytes
int sceSblGcAuthMgrPcactGetChallengeForDriver(SceUID id, const char *entropy, char *challenge);

SceSblGcAuthMgrPcactForDriver_B7AE58B9

typedef struct ScePcactCreateChallengeOpt {
    char length;      // must be 0x10
    char unk[15];     // must be zeroed
    char entropy[32]; // epassword
} ScePcactCreateChallengeOpt;

// challenge size is 0x80 bytes
// prng size is 0x40 bytes
int SceSblGcAuthMgrPcactForDriver_B7AE58B9(SceUInt mode, ScePcactCreateChallengeOpt *pOpt, uint64_t *rtc_tick, void *challenge, void *prng);

get_aes_dec_key

aes_dec_key is derived from act_data. prng seems to be a temporary work buffer.

// prng size is 0x40 bytes
// aes_dec_key size is 0x10 bytes
int get_aes_dec_key(const ScePcactActivationData *act_data, void *prng, void *aes_dec_key);

SceSblGcAuthMgrMlnpsnlForDriver

sceSblGcAuthMgrMlnpsnlAuth1ForDriver

sceSblGcAuthMgrMlnpsnlAuth2ForDriver

SceSblGcAuthMgrPkgForDriver

sceSblGcAuthMgrPkgVryForDriver

Calls F00D_Commands#0x11_kirk_ecc160_verify KIRK command 0x11 to verify PKG ECDSA signature.

// pHash: sha1 hash of data (0x14 bytes)
// pSig: ECDSA signature (2 * 0x14 bytes)
int sceSblGcAuthMgrPkgVryForDriver(const char *pHash, const char *pSig);

SceSblGcAuthMgrSclkForDriver

Related to Secure clock.

sceSblGcAuthMgrSclkGetData1ForDriver

AES256ECB encrypts a buffer made from a "genuine random number" followed by zeroes.

typedef struct SceSblGcAuthMgrSclkData1 { // size is 0x30
  int unk_0; // ex: 1
  int unk_4; // ex: 1
  int unk_8; // ex: 0
  int unk_C; // ex: 0
  char enc_data_0[0x10]; // seed = zeroes
  char enc_data_1[0x10]; // seed = hardcoded
} SceSblGcAuthMgrSclkData1;

int sceSblGcAuthMgrSclkGetData1ForDriver(SceSblGcAuthMgrSclkData1 *pData);

sceSblGcAuthMgrSclkSetData2ForDriver

Checks header, sha256, AES256ECB decrypts then sets some secure RTC.

typedef struct SceSblGcAuthMgrSclkData2 { // size is at least 0x30
  int unk_0; // ex: 1
  int unk_4; // ex: 1
  int unk_8; // ex: 0
  int unk_C; // ex: 0
  char enc_data_0[0x10];
  char enc_data_1[0x10];
  // more, maybe sha256
} SceSblGcAuthMgrSclkData2;

int sceSblGcAuthMgrSclkSetData2ForDriver(SceSblGcAuthMgrSclkData2 *pData);

SceSblGcAuthMgrGcAuthForDriver

cmd56_handshake

This is a wrapper function that starts initialization subroutine through SceKernelThreadMgr#_sceKernelExtendKernelStackWideForDriver.

int cmd56_handshake(int sd_ctx_index);

SceSblGcAuthMgrPsmactForDriver

get_act_data

Executes KIRK command 0x1000B 19.

// data is of size 0x80
int get_act_data(void* data);

SceSblGcAuthMgrMsSaveBBForDriver

sceSblGcAuthMgrMsSaveBBCipherInitForDriver

AES encrypts with null IV using a Kirk command.

sceSblGcAuthMgrMsSaveBBMacInitForDriver

int sceSblGcAuthMgrMsSaveBBMacInitForDriver(void *pDst, SceUInt32 initValue);

sceSblGcAuthMgrMsSaveBBMacUpdateForDriver

AES encrypts a 0x800 buffer.

sceSblGcAuthMgrMsSaveBBCipherFinalForDriver

sceSblGcAuthMgrMsSaveBBMacFinalForDriver

sceSblGcAuthMgrMsSaveBBCipherUpdateForDriver

AES decrypts a 0x800 buffer then AES decrypts with null IV using a Kirk command.

SceSblGcAuthMgr

_sceSblGcAuthMgrPcactActivation

int _sceSblGcAuthMgrPcactActivation(const ScePcactActivationData *act_data, SceSize act_data_size);

_sceSblGcAuthMgrMsSaveBBCipherInit

_sceSblGcAuthMgrAdhocBB160Shutdown

_sceSblGcAuthMgrAdhocBB160UniCastEncrypt

_sceSblGcAuthMgrAdhocBB160GetKeys

_sceSblGcAuthMgrGetMediaIdType01

Returns MediaIdType01 by using Kirk command 0x23 on a global buffer.

typedef struct SceMediaIdType01 {
  char enc_data[0x10]; // encrypted data
  char enc_data_cmac[0x10]; // CMAC of encrypted data
} SceMediaIdType01;

int _sceSblGcAuthMgrGetMediaIdType01(SceMediaIdType01 **pMediaId);

_sceSblGcAuthMgrMsSaveBBCipherFinal

_sceSblGcAuthMgrAdhocBB160BroadCastDecrypt

_sceSblGcAuthMgrPsmactVerifyR1

_sceSblGcAuthMgrAdhocBB224Auth1

_sceSblGcAuthMgrMsSaveBBMacInit

_sceSblGcAuthMgrPsmactCreateC1

_sceSblGcAuthMgrPkgVry

typedef struct SceSblGcAuthMgrPkgVryInfo { // size is 0x10
  SceSize hashSize; // ex: 0x14
  SceSize sigSize; // ex: 0x28
  SceUInt64 reserved;
} SceSblGcAuthMgrPkgVryInfo;

// pHash: sha1 hash of data (0x14 bytes)
// pSig: ECDSA signature (2 * 0x14 bytes)
int _sceSblGcAuthMgrPkgVry(const char *pHash, const char *pSig, SceSblGcAuthMgrPkgVryInfo *pInfo);

_sceSblGcAuthMgrAdhocBB224Auth5

_sceSblGcAuthMgrAdhocBB224Init

_sceSblGcAuthMgrAdhocBB224Auth4

_sceSblGcAuthMgrAdhocBB160Auth1

_sceSblGcAuthMgrAdhocBB160BroadCastEncrypt

_sceSblGcAuthMgrMsSaveBBMacUpdate

_sceSblGcAuthMgrAdhocBB224Auth2

_sceSblGcAuthMgrAdhocBB160Auth4

_sceSblGcAuthMgrSclkSetData2

_sceSblGcAuthMgrSclkGetData1

_sceSblGcAuthMgrAdhocBB224Shutdown

_sceSblGcAuthMgrPcactGetChallenge

typedef struct ScePcactGetChallengeOpt { // size is 0x10 on FWs 0.990-3.60
  SceSize entropySize; // Maximum size is 0x20 bytes
  SceSize challengeSize; // Maximum size is 0x80 bytes
  char reserved[8];
} ScePcactGetChallengeOpt;

int _sceSblGcAuthMgrPcactGetChallenge(int id, const char *entropy, char *challenge, ScePcactGetChallengeOpt *pOpt);

_sceSblGcAuthMgrAdhocBB224GetKeys

_sceSblGcAuthMgrAdhocBB160Auth3

_sceSblGcAuthMgrAdhocBB160Auth2

_sceSblGcAuthMgrAdhocBB224Auth3

_sceSblGcAuthMgrAdhocBB160UniCastDecrypt

_sceSblGcAuthMgrAdhocBB160Auth5

_sceSblGcAuthMgrAdhocBB160Init

_sceSblGcAuthMgrMsSaveBBCipherUpdate

_sceSblGcAuthMgrMsSaveBBMacFinal

gcauthmgr_sm calls to Kirk commands in cmep

The use of os0:sm/gcauthmgr_sm.self is to support the new generation of Kirk. It uses a similar input structure to the original Kirk on the PSP.

PSP Kirk support

4, 7, 0xC, 0xD, 0xE, 0x10, 0x11, 0x12 are the classic PSP Kirk services supported by gcauthmgr_sm. However, keys and seeds are sometimes different and look similar to PS3 crypto.

New PS Vita Kirk services

0x14-0x19, 0x1B-0x23 are the new Kirk services supported by gcauthmgr_sm. Most are just 224bit versions of original Kirk commands.

• 0x14 is the 224bit version of ECDSA key pair gen (Kirk command 0xC). The only input is an empty buffer size (3*0x1C) it returns 3 values: Private key, Public X point, Public Y point. Each value is 0x1C bytes long.
• 0x16 is the 224bit version of pseudo random number generator (Kirk command 0xE). It will return 0x1C bytes of random data into the buffer.
• 0x17-0x19 are the 224bit ECDSA versions of PSP's 160bit Kirk commands 0x10-0x12.
• 0x1B-0x23 have no equivalent on PSP Kirk but are maybe also present on PS3

PSN Activation Block

On 7/29/2017, all hacked Vitas on 3.60 spoofing the latest firmware (3.65) were blocked from console activation. This is particularly odd because the PSN passphrase did not change in 3.65. Additionally with the release of [ensō](https://enso.henkaku.xyz/) added to the confusion of what happened. Here is the result of a preliminary investigation of the situation.

Upon game activation, the Vita displays an dialog that shows the error number E-80558325. This error number is used in SceNpKdc, which is found in vs0:external/np_kdc.suprx. The error code itself is created when the activation response is received:

v5 = v45 | 0x80558300;

Here, v5 is the return code and v45 is the string error code from the server converted to a number. The request made to Sony's server looks like the following

Content-Type: application/x-www-form-urlencoded
User-Agent: My heart leaps up when I behold A rainbow in the sky
X-I-5-DRM-Version: 1.0

loginid=PSNID&epassword=ENCRYPTEDPASSWORD&platform=psp2&c1=CHALLENGESTRING

The request from a 3.65 stock console has the same headers and loginid and epassword (for the same account) so the only change visible to Sony is the challenge string c1.

The response you get on 3.60 is

HTTP/1.0 200 OK
Server: Apache
X-I-5-DRM-Version: 1.0
X-I-5-DRM-Status: NG; reason=25
Content-Length: 0
Content-Type: application/x-i-5-drm
X-N: S
Date: Sat, 29 Jul 2017 23:01:31 GMT
Connection: keep-alive

Challenge

The challenge string is constructed in SceNpKdc with a call to SceLibKernel_9557D15C. Farther investigation shows that SceLibKernel_9557D15C likely has the following call type:

int sceKernelPcactGetChallenge(int id, const char entropy[32], char challenge[128]);

It is called with id = 0 and entropy set to uninitialized stack space. Tracing this call, you eventually arrive at a kernel function in SceSblGcAuthMgrPcactForDriver with the NID 0xB7AE58B9. This call looks like the following

typedef struct {
    uint8_t length;      // must be 16
    uint8_t unk[15];     // must all be 0
    uint8_t entropy[32]; // from user
} challengeInput_t;

int createPcactChallenge(int id, const challengeInput_t *in, uint64_t *rtc_seconds, char challenge[128], char output[16]);

It appears that data from aimgr_sm.self (F00D Commands) along with in, rtc_seconds (the RTC in seconds), DMAC engine, and maybe other data are entangled together into a 0x70-byte sized block. Then a 20 byte SHA1-HMAC is computed over the buffer with some key. It is likely that the data itself is unimportant and just has to be random and console unique.

This is the challenge string generation code, reverse engineered from PSP openpsid.prx (almost same code as in PS Vita):

#define KIRK_CMD_ENCRYPT_IV_0 4
#define KIRK_CMD_DECRYPT_IV_0 7
#define KIRK_CMD_SHA1_HASH 11
#define KIRK_CMD_PRNG 14

static int DecryptIV0(u32 *buf, u32 size, u32 code) {
	buf[0] = 5;
	buf[1] = 0;
	buf[2] = 0;
	buf[3] = code;
	buf[4] = size;

	return sceUtilsBufferCopyWithRange(buf, size+0x14, buf, size+0x14, KIRK_CMD_DECRYPT_IV_0);
}

static int EncryptIV0(u32 *buf, u32 size, u32 code) {
	buf[0] = 4;
	buf[1] = 0;
	buf[2] = 0;
	buf[3] = code;
	buf[4] = size;

	return sceUtilsBufferCopyWithRange(buf, size+0x14, buf, size+0x14, KIRK_CMD_ENCRYPT_IV_0);
}

static int generate_challenge(u8 mode, u8 *psid, u8 *entropy, u64 *rtc_tick, u8 *challenge, u8 *prng) {
	static u8 data_38BC[0x10] = { 0x38, 0x0A, 0x18, 0x0E, 0x36, 0x58, 0xBC, 0xC1, 0x70, 0x64, 0x69, 0xE3, 0x29, 0x60, 0x81, 0xF9 };
	static u8 data_38DC[0x10] = { 0xCA, 0x0E, 0x20, 0x6E, 0xCE, 0xE6, 0xFB, 0x66, 0x68, 0x28, 0x65, 0x42, 0xEF, 0x4F, 0xF8, 0x8F };
	static u8 work[0xB8];
	static u8 challenge_work[0x70];

	int res;
	int i;

	memset(work, 0, 0xB8);
	memset(challenge_work, 0, 0x70);

	memset(challenge, 0, 0x80);
	memset(prng, 0, 0x40);

	// get random data
	res = sceUtilsBufferCopyWithRange(work, 0x14, 0, 0, KIRK_CMD_PRNG);
	if (res < 0)
		return -2;

	memcpy(prng, work, 0x10);

	// encrypt prng
	memcpy(work+0x14, prng, 0x10);
	res = DecryptIV0(work, 0x10, 0x68);
	if (res < 0)
		return -3;

	memcpy(prng+0x10, work, 0x10);
	prng[0x20] = mode;

	memcpy(challenge_work, work, 0x10);              // random data
	memcpy(challenge_work+0x10, data_38DC, 0x10);    // constant data

	// encrypt psid
	memcpy(work+0x14, psid, 0x10);
	res = DecryptIV0(work, 0x10, 0x68);
	if (res < 0)
		return -3;

	memcpy(challenge_work+0x20, work, 0x10);         // encrypted psid
	memcpy(challenge_work+0x30, rtc_tick, 0x8);      // rtc tick 
	memcpy(challenge_work+0x38, entropy+0x10, 0x20); // entropy, 32 bytes of epassword

	// fuseid
	u32 fuseid0 = *(u32 *)0xBC100090;
	u32 fuseid1 = *(u32 *)0xBC100094;
	challenge_work[0x58] = fuseid1 >> 24;
	challenge_work[0x59] = fuseid1 >> 16;
	challenge_work[0x5A] = fuseid1 >> 8;
	challenge_work[0x5B] = fuseid1;
	challenge_work[0x5C] = fuseid0 >> 24;
	challenge_work[0x5D] = fuseid0 >> 16;
	challenge_work[0x5E] = fuseid0 >> 8;
	challenge_work[0x5F] = fuseid0;

	memcpy(work+0x14, challenge_work, 0x60);

	// xor with data_38BC keys
	for (i = 0; i < 0x60; i++) {
		work[0x14+i] ^= data_38BC[i % 0x10];
	}

	// encrypt data
	res = EncryptIV0(work, 0x60, 0x13);
	if (res < 0)
		return -4;
	
	// xor encrypted data with data_38BC keys
	for (i = 0; i < 0x60; i++) {
		work[0x14+i] ^= data_38BC[i % 0x10];
	}

	// build challenge string
	memset(challenge_work, 0, 0x10);
	challenge_work[0x00] = 0x11;
	challenge_work[0x01] = 0x01;
	challenge_work[0x02] = mode;
	memcpy(challenge_work+0x10, work+0x14, 0x60);

	// get sha1 hash digest
	*(u32 *)work = 0x80;
	memcpy(work+0x04, data_38BC, 0x10);
	memcpy(work+0x14, challenge_work, 0x70);
	res = sceUtilsBufferCopyWithRange(work, 0x84, work, 0x84, KIRK_CMD_SHA1_HASH);
	if (res < 0)
		return -5;

	// encrypt hash digest
	memcpy(work+0x14, work, 0x10);
	res = EncryptIV0(work, 0x10, 0x13);
	if (res < 0)
		return -4;

	// copy challenge string
	memcpy(challenge, challenge_work, 0x70);
	memcpy(challenge+0x70, work+0x14, 0x10);

	return 0;
}

How Sony Blocked Activation

There are at least two possible ways. First is that on 3.65, the random-looking data block has some specific structure that Sony looks for (or some console unique data in this block gives away the fact that the console is on 3.60). Second is that they changed the SHA1-HMAC key. If it is the latter case, then the next step is to find how this key is constructed. It is likely that the key is constructed in F00D and therefore spoofing it would require a F00D hack.

How Hackers Bypassed The Block

See ReStore / ReNpDrm vulnerability by CelesteBlue.

How Sony Unblocked Activation

Since May 2018, the challenge string in requests sent from PSVita to PSN for Content and PSN Account activations is not checked anymore. Strange...

I can think about 4 reasons:

1) Sony wanted to fight ReStore by killing its purpose. In this case, they would have better patched the vulnerability...

2) Sony has done that by mistake. Impossible.

3) Sony is working on a more secure PSN. We have an exemple: when Sony removed ConsoleId checks on its servers for 3 months, then restored the check with even more securities. In the PSVita case, they would have been quicker at fixing challenge if that was for security.

4) Sony is working on a big change of PSN. This is very plausible since we discovered that they are adapting old PSN to work with a new "Account Id" because now people can change PSN ID.