Ernie: Difference between revisions
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Ernie is the codename for the Syscon chip. The Syscon is responsible for handling button input (including power button), | Ernie is the codename for the Syscon chip. The Syscon is for exemple responsible for handling button input (including power button), reading/writing to non-volatile storage (NVS) for storing system flags (mostly encrypted and signed). For example IDU flag is stored in NVS. Syscon is also responsible for maintaining the physical address to the resume buffer during [[Suspend]]. Communication between [[Kermit]] and Syscon is mainly through SPI (see [[SceSyscon]]) but there are also some GPIO pins connecting the two. The chip model is NEC/Renesas <code>uPD79F0109</code> and is likely custom designed for Sony. | ||
See also: [[Ernie Secure]] | |||
= Boot Process = | = Boot Process = | ||
Line 98: | Line 100: | ||
</pre> | </pre> | ||
Then another set of shared sequence. Some differences in the warmboot responses though. On line 18, <pre>FF BF FF 74</pre> becomes <pre>FF FF FF 74</pre>. On line 12, the <pre>00 00 00 00</pre> becomes the address of the resume buffer | Then another set of shared sequence. Some differences in the warmboot responses though. On line 18, <pre>FF BF FF 74</pre> becomes <pre>FF FF FF 74</pre>. On line 12, the <pre>00 00 00 00</pre> becomes the physical address of the resume context buffer. Example: | ||
<pre>F0 1E 1F 41</pre> | |||
<pre> | <pre> | ||
Line 159: | Line 162: | ||
= Packet checksum = | = Packet checksum = | ||
The checksum byte of the packet is calculated as the binary negation of the sum of the packet (including the 2 bytes of the command id and the byte for the length). | The checksum byte of the packet is calculated as the binary negation of the sum of all the bytes of the packet (including the 2 bytes of the command id and the byte for the length). | ||
The checksum calculation can be implemented as follows: | The checksum calculation can be implemented as follows: | ||
<source lang="c"> | <source lang="c"> | ||
Line 178: | Line 181: | ||
Commands are listed in the order seen in cold boot. The numbers in the captured packets indicate the assumed order with some unused packets filtered out (they appear to be resent). The ordering and grouping are assumed and may contain errors. | Commands are listed in the order seen in cold boot. The numbers in the captured packets indicate the assumed order with some unused packets filtered out (they appear to be resent). The ordering and grouping are assumed and may contain errors. | ||
== CMD 0x0001 == | == CMD 0x0001 - sceSysconGetErnieVersion == | ||
Gets | |||
Gets version of the current installed Ernie firmware. Can also be seen in the packet header in [[Syscon Update]]. Also sent at kernel boot. | |||
<pre> | <pre> | ||
SEND 1 > [2.881037083333333] 0x0001, payload=[ | ], chk=0xFD | SEND 1 > [2.881037083333333] 0x0001, payload=[ | ], chk=0xFD | ||
Line 189: | Line 194: | ||
</pre> | </pre> | ||
== CMD 0x0005 - | == CMD 0x0005 - sceSysconGetHardwareInfo == | ||
See [[KBL Param#Hardware_Info]]. | |||
<pre> | <pre> | ||
SEND 2 > [2.881578833333333] 0x0005, payload=[ | ], chk=0xF9 | SEND 2 > [2.881578833333333] 0x0005, payload=[ | ], chk=0xF9 | ||
Line 197: | Line 203: | ||
</pre> | </pre> | ||
== CMD 0x0002 == | == CMD 0x0002 - sceSysconGetTimeStamp == | ||
Gets | |||
Gets Ernie firmware timestamp. Also sent at kernel boot. | |||
<pre> | <pre> | ||
SEND 3 > [2.882249083333333] 0x0002, payload=[ | ], chk=0xFC | SEND 3 > [2.882249083333333] 0x0002, payload=[ | ], chk=0xFC | ||
Line 209: | Line 217: | ||
== CMD 0x0080 == | == CMD 0x0080 == | ||
Unknown. Sends data 0x0012 on 3.60. Does not get return data. Also sent at kernel boot. | |||
Unknown. Sends data 0x0012 on FW 3.60. Does not get return data. Also sent at kernel boot. | |||
<pre> | <pre> | ||
SEND 4 > [2.895635416666666] 0x0080, payload=[12 00 | ..], chk=0x6A | SEND 4 > [2.895635416666666] 0x0080, payload=[12 00 | ..], chk=0x6A | ||
Line 222: | Line 232: | ||
</pre> | </pre> | ||
== CMD 0x0010 == | == CMD 0x0010 - sceSysconGetWakeupFactor == | ||
See [[KBL Param#Wakeup Factor|Wakeup Factor]]. | |||
Boot type indicator. 0xFF14 on cold boot. 0xFF80 on resume boot. | Boot type indicator. 0xFF14 on cold boot. 0xFF80 on resume boot. | ||
<pre> | <pre> | ||
Line 229: | Line 242: | ||
</pre> | </pre> | ||
== CMD 0x00A0 == | == CMD 0x00A0 - Handshake == | ||
Runs twice. Appears to contain a 8 byte inner header. First packet sends all zeros and gets back a 8 byte random response. This is likely a nonce or challenge. This likely establishes an encrypted session. Encrypted data differs on each boot. There does not appear to be data transferred using the established session. | Runs twice. Appears to contain a 8 byte inner header. First packet sends all zeros and gets back a 8 byte random response. This is likely a nonce or challenge. This likely establishes an encrypted session. Encrypted data differs on each boot. There does not appear to be data transferred using the established session. | ||
<pre> | <pre> | ||
SEND 6 > [2.994470666666667] 0x00A0, payload=[30 00 00 0B 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xFB | SEND 6 > [2.994470666666667] 0x00A0, payload=[30 00 00 0B 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xFB | ||
Line 243: | Line 258: | ||
</pre> | </pre> | ||
== CMD 0x088E == | == CMD 0x088E - sceSysconCtrlVoltage == | ||
Controls voltage. Sends value 0x2201 on FW 3.60 and does not get any response. | |||
<pre> | <pre> | ||
SEND 8 > [3.061354583333333] 0x088E, payload=[01 22 | ."], chk=0x43 | SEND 8 > [3.061354583333333] 0x088E, payload=[01 22 | ."], chk=0x43 | ||
Line 253: | Line 270: | ||
</pre> | </pre> | ||
== CMD 0x1082 == | == CMD 0x1082 - NVS Read == | ||
Get data from [[#NVS|NVS]]. 2-byte offset followed by 1 byte length. For example used to fetch boot-time flags, like Update Mode. | |||
<pre> | <pre> | ||
Get Qaf Token area: | |||
SEND 9 > [3.078212500000000] 0x1082, payload=[80 04 08 | ...], chk=0xDD | SEND 9 > [3.078212500000000] 0x1082, payload=[80 04 08 | ...], chk=0xDD | ||
RESP 9 < [3.069790250000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 | RESP 9 < [3.069790250000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 | ||
Line 261: | Line 281: | ||
RESP 9 < [3.078212500000000] 0x0024, flags=00, payload=[FF FF FF FF 01 FF FF FF | ........], chk=0xD7, unk=0x77 | RESP 9 < [3.078212500000000] 0x0024, flags=00, payload=[FF FF FF FF 01 FF FF FF | ........], chk=0xD7, unk=0x77 | ||
Get Update Mode: | |||
SEND 10 > [3.094879833333333] 0x1082, payload=[A0 04 01 | ...], chk=0xC4 | SEND 10 > [3.094879833333333] 0x1082, payload=[A0 04 01 | ...], chk=0xC4 | ||
RESP 10 < [3.086322916666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0xFF | RESP 10 < [3.086322916666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0xFF | ||
Line 267: | Line 288: | ||
</pre> | </pre> | ||
== CMD 0x1100 == | == CMD 0x1100 - sceSysconGetErnieDLVersion == | ||
Gets Ernie DownLoader Version i.e. version of Ernie firmware. | |||
<pre> | <pre> | ||
SEND 11 > [3.099025500000000] 0x1100, payload=[ | ], chk=0xED | SEND 11 > [3.099025500000000] 0x1100, payload=[ | ], chk=0xED | ||
Line 274: | Line 297: | ||
</pre> | </pre> | ||
== CMD 0x00D0 == | == CMD 0x00D0 - Handshake before SNVS RW == | ||
Some encrypted transfer that looks close to [[Syscon#CMD 0x00A0]] in format. Different on each boot. | Some encrypted transfer that looks close to [[Syscon#CMD 0x00A0]] in format. Different on each boot. | ||
<pre> | <pre> | ||
Line 296: | Line 320: | ||
</pre> | </pre> | ||
== CMD 0x00D2 == | == CMD 0x00D2 - SNVS RW == | ||
This command is used twice during boot and also quite often after boot. Data is different on each boot. Encrypted session using key from handshake above. Second transaction | |||
This command is used twice during boot and also quite often after boot. Data is different on each boot. Encrypted session using key from handshake above. Second transaction is the firmware version data written during the update process. | |||
<pre> | <pre> | ||
SEND 15 > [3.204733083333333] 0x00D2, payload=[32 78 88 CF 3E 63 56 19 75 3A 0A 2D F3 49 63 E2 | 2x..>cV.u:.-.Ic.], chk=0xA4 | SEND 15 > [3.204733083333333] 0x00D2, payload=[32 78 88 CF 3E 63 56 19 75 3A 0A 2D F3 49 63 E2 | 2x..>cV.u:.-.Ic.], chk=0xA4 | ||
Line 312: | Line 337: | ||
</pre> | </pre> | ||
== CMD 0x0090 == | == CMD 0x0090 - sceSysconReadScratchPad == | ||
This | |||
This command reads data from Ernie Scratch Pad. This is the inverse of command 0x91. | |||
This is used for example to fetch the saved resume context buffer physical address. Kernel sets this before suspending and this value is passed to the resume function. See [[Suspend]]. The format is 2 byte offset and 1 byte length. | |||
<pre> | <pre> | ||
SEND 16 > [3.221743166666667] 0x0090, payload=[0C 00 04 | ...], chk=0x5B | SEND 16 > [3.221743166666667] 0x0090, payload=[0C 00 04 | ...], chk=0x5B | ||
Line 321: | Line 350: | ||
</pre> | </pre> | ||
== CMD 0x0800 == | == CMD 0x0091 - sceSysconWriteScratchPad == | ||
This command writes data to Ernie Scratch Pad. This is the inverse of command 0x90. | |||
== CMD 0x0800 - SceSysconForDriver_A2FE9BF9 == | |||
See [[KBL Param]]. | |||
<pre> | <pre> | ||
SEND 17 > [3.225828583333334] 0x0800, payload=[ | ], chk=0xF6 | SEND 17 > [3.225828583333334] 0x0800, payload=[ | ], chk=0xF6 | ||
Line 328: | Line 363: | ||
</pre> | </pre> | ||
== CMD 0x0100 == | == CMD 0x0100 - sceSysconGetControlsInfo == | ||
See [[KBL Param#Boot Controls Info|Boot Controls Info]]. | |||
<pre> | <pre> | ||
SEND 18 > [3.226331500000000] 0x0100, payload=[ | ], chk=0xFD | SEND 18 > [3.226331500000000] 0x0100, payload=[ | ], chk=0xFD | ||
Line 335: | Line 372: | ||
</pre> | </pre> | ||
== CMD 0x0003 == | == CMD 0x0003 - sceSysconGetSleepFactor == | ||
See [[KBL Param#Sleep Factor|Sleep Factor]]. | |||
<pre> | <pre> | ||
SEND 19 > [3.226820750000000] 0x0003, payload=[ | ], chk=0xFB | SEND 19 > [3.226820750000000] 0x0003, payload=[ | ], chk=0xFB | ||
Line 342: | Line 381: | ||
</pre> | </pre> | ||
== CMD 0x0006 == | == CMD 0x0006 - sceSysconGetHardwareInfo2 == | ||
See [[KBL Param#Hardware Info 2|Hardware Info 2]]. | |||
<pre> | <pre> | ||
SEND 20 > [3.227328833333333] 0x0006, payload=[ | ], chk=0xF8 | SEND 20 > [3.227328833333333] 0x0006, payload=[ | ], chk=0xF8 | ||
Line 349: | Line 390: | ||
</pre> | </pre> | ||
== CMD 0x088E == | == CMD 0x088E - sceSysconCtrlVoltage == | ||
Last command sent before a time-jump (likely indicating completion of early-boot). | |||
<pre> | <pre> | ||
SEND 22 > [3.386554833333333] 0x088E, payload=[02 29 | .)], chk=0x3B | SEND 22 > [3.386554833333333] 0x088E, payload=[02 29 | .)], chk=0x3B | ||
Line 360: | Line 402: | ||
== CMD 0x0004 == | == CMD 0x0004 == | ||
Unknown. Likely happens after initial boot. | Unknown. Likely happens after initial boot. | ||
<pre> | <pre> | ||
Line 366: | Line 409: | ||
</pre> | </pre> | ||
== CMD 0x0103 == | == CMD 0x0103 - sceSysconGetMultiCnInfo == | ||
Likely happens after initial boot. | |||
<pre> | <pre> | ||
SEND 27 > [4.177586083333333] 0x0103, payload=[ | ], chk=0xFA | SEND 27 > [4.177586083333333] 0x0103, payload=[ | ], chk=0xFA | ||
Line 373: | Line 418: | ||
</pre> | </pre> | ||
= Syscon Scratch Pad = | |||
{| class="wikitable" | |||
|- | |||
! Offset !! Size !! Name !! Comment !! Used by | |||
|- | |||
| 0x0 || 8 || unknown || || | |||
|- | |||
| 0x8 || 4 || Syscon power on time || ex on DevKit: 0xA, 0x16, 0x1F, 0x24. ex on retail: 0x01BC0CD0, 0x05AC1AF7, 0x80000269 || [[SceRtc#sceRtcSetCurrentTickForDriver]] | |||
|- | |||
| 0xC || 4 || Resume context physical address || Set on retail. Not set on DevKit. ex: 0x411F1EF0 || second_loader | |||
|- | |||
| 0x10 || 5 || Current Tick || Set on retail and DevKit. Stored in microseconds since 01/01/0001 divided by 2^19. || [[SceRtc#sceRtcSetCurrentTickForDriver]] | |||
|- | |||
| 0x15 || 3 || Padding of Current Tick || || | |||
|- | |||
| 0x18 || 5 || Current Secure Tick || Set on retail. Not set on DevKit. || [[SceRtc#sceRtcSetCurrentSecureTickForDriver]] | |||
|- | |||
| 0x1D || 5 || Current Network Tick || Always a bit earlier than Current Tick and Current Secure Tick. || [[SceRtc#sceRtcSetCurrentNetworkTickForDriver]] | |||
|- | |||
| 0x22 || 5 || Current ?Debug Secure?/?Tool Secure? Tick || Set on DevKit. Not set on retail. || [[SceRtc#sceRtcGetCurrentToolSecureTickForDriver]] | |||
|- | |||
| 0x27 || 5 || Current Aux Tick || || [[SceRtc#sceRtcSetCurrentAuxTickForDriver]] | |||
|- | |||
| 0x2C || 5 || Current Debug Network Tick || || [[SceRtc#sceRtcSetCurrentDebugNetworkTickForDriver]] | |||
|- | |||
| 0x31 || 0x8F || unknown || Maybe reserved. Probably unused. || | |||
|- | |||
| 0xE0 || 0x20 || [[KBL Param|CP DIP Switches]] || Set on DevKit having a CP. Hence not set on Retail nor TestKit. || ?secure_kernel? before system suspend, second_loader after system resume | |||
|} | |||
== Types == | |||
<source lang="C"> | |||
typedef struct SceSysconRtcTick { // size is 5 bytes | |||
uint8_t tick[5]; | |||
} SceSysconRtcTick; | |||
typedef struct SceSysconScratchPad { // size is 0x100 bytes | |||
uint8_t unk_0[8]; | |||
SceUInt32 powerOnTime; | |||
void *resumeContextPA; | |||
SceRtcSysconTick currentTick; | |||
uint8_t padding[3]; | |||
SceSysconRtcTick currentSecureTick; | |||
SceSysconRtcTick currentNetworkTick; | |||
SceSysconRtcTick unk_0x22; | |||
SceSysconRtcTick currentAuxTick; | |||
SceSysconRtcTick currentDebugNetworkTick; | |||
uint8_t reserved[0x8F]; | |||
SceDIPSW dipsw; | |||
} SceSysconScratchPad; | |||
</source> | |||
= NVS = | |||
Ernie Non-volatile storage (NVS) is a persistent storage allocated on Ernie Data Flash that is used by PS Vita OS for data required at boot time. Indeed, reading NVS requires no driver except the driver to communicate with Syscon, whilst reading PS Vita eMMC requires its AES-XTS decryption. | |||
Not every NVS sector is directly readable from Kermit: the first sectors are part of [[Ernie Secure#SNVS|SNVS]] (Secure NVS) which means that they are XTS-encrypted and must be accessed through a Secure handshake. | |||
NVS actual size is 0xBA0 bytes on new Syscon hardware revisions and 0xC20 on old. However, only 0xB60 bytes are accessible from Kermit on System Software 3.600.011 and more recent. The hidden area is probably used internally by Syscon as it is not blanked nor 0xFFed. | |||
On FW 3.60, NVS size accessible from Kermit is 0xB60 bytes: | |||
* Area from 0 to 0x3FF is named [[Ernie Secure#SNVS]]. It has an additional level of encryption. It cannot be read using [[SceSblSsMgr#sceSblNvsReadForKernel]] nor written using [[SceSblSsMgr#sceSblNvsWriteForKernel]]. This area is handled by [[Secure Modules]]. | |||
* Area from 0x400 to 0x75F is handled by Non-secure Kernel [[SceSblSsMgr]] module. | |||
* Area from 0x760 to 0xB5F is reserved for Test and Tool consoles. However this area seems unused. | |||
* Area from 0xB60 to the end of NVS is not accessible from Kermit. | |||
{| class="wikitable" | |||
|- | |||
! Offset !! Size !! Name !! Comment !! Used by | |||
|- | |||
| 0 || 0x400 || SNVS || See [[Ernie Secure#SNVS]]. || | |||
|- | |||
| 0x400 || 0x80 || Qaf Token || || second_loader | |||
|- | |||
| 0x480 || 0x1 || Qaf Token Flag || 1 when Qaf Token is not set (FFed), 0 when Qaf Token is set || second_loader | |||
|- | |||
| 0x481 || 0x1 || Extra UART Flag || 0xFF - extra UART disabled, 0x00 - extra UART enabled, 0x01 - extra UART enabled only when Jig dongle is connected || second_loader | |||
|- | |||
| 0x482 || 0x1 || Unknown || || [[SceSblSsMgr#sceSblSsGetNvsDataForDriver]], [[SceSblSsMgr#sceSblSsSetNvsDataForDriver]] | |||
|- | |||
| 0x483 || 0x1 || Safe Mode Flags || 0xFF - not safe mode, 1, 3, 5, 9, 0x11 - safemode type || [[SceSblSsMgr#sceSblSsGetNvsDataForDriver]], [[SceSblSsMgr#sceSblSsSetNvsDataForDriver]], second_loader, set by [[SceShellSvc#sceShellUtilRequestRebootWithError]], read by [[SceSafeMode]] | |||
|- | |||
| 0x484 || 0x1 || <code>KervResult</code>/<code>KervDiagResultFlag</code> || || Factory test <code>preCheckFactTest</code> | |||
|- | |||
| 0x485 || 0x1 || Unknown || || | |||
|- | |||
| 0x486 || 0x1 || <code>MCEmu</code> Flag (use internal <code>ux0</code>) || 0xFF on FAT - no internal storage or on PS TV or Slim - internal storage enabled, 0xFE on PS TV or Slim - internal storage disabled <br>Not present on FWs 0.931-0.990. Present on FW 3.60. Maybe not used on FWs <= 0.995 || [[SceSblSsMgr#sceSblSsGetNvsDataForDriver]], [[SceSblSsMgr#sceSblSsSetNvsDataForDriver]], second_loader | |||
|- | |||
| 0x487 || 0x1 || Unknown || 0xFF - unknown, maybe not used on FWs <= 0.995 || second_loader | |||
|- | |||
| 0x4A0 || 0x1 || Update Mode || 0xFF - not update mode, other value - update step (to detail) || [[SceSblUpdateMgr#sceSblUsGetUpdateModeForUser]], [[SceSblUpdateMgr#sceSblUsSetUpdateModeForUser]] | |||
|- | |||
| 0x4A1 || 0x3 || Unknown. Unused. || || | |||
|- | |||
| 0x4A4 || 0x4 || System Language || || [[SceRegistryMgr]], [[SceSblSsMgr#sceSblSsGetNvsDataForDriver]], [[SceSblSsMgr#sceSblSsSetNvsDataForDriver]] | |||
|- | |||
| 0x4A8 || 0x1C || Unknown. Unused. || || | |||
|- | |||
| 0x4C4 || 0x1 || Unknown. Set to 0 by default. || || | |||
|- | |||
| 0x4C5 || 0x1B || Unknown. Unused. || || | |||
|- | |||
| 0x4E0 || 0x20 || KibanID || || Per-console ASCII string of length 22 characters. This is a serial number also present in PS3 and PS4 Serial Flash. [[SceSblSsMgr#sceSblSsGetNvsDataForDriver]], [[SceSblSsMgr#sceSblSsSetNvsDataForDriver]] | |||
|- | |||
| 0x500 || 0x1 || Wlan/Bt Flag || || [[SceSblSsMgr#sceSblSsGetNvsDataForDriver]], [[SceSblSsMgr#sceSblSsSetNvsDataForDriver]], [[SceWlanBt]] module_start | |||
|- | |||
| 0x501 || 0x1F || Unknown. Unused. || || | |||
|- | |||
| 0x520 || 0x80 || Activation Area || first 0x20 bytes are SceNVSKitActivationData || [[SceSblSsMgr]], [[SceSblPostSsMgr]] | |||
|- | |||
| 0x5A0 || 0x100 || Qaf Token RSA signature || Not present on FW 0.990. Present on FW 3.60. Maybe added on FW 1.80. || second_loader | |||
|- | |||
| 0x6A0 || 0xC0 || Unknown. Unused. || || | |||
|- | |||
| 0x760 || 0x400 || Reserved for Test and Tool consoles. || Seems unused. || | |||
|} | |||
== Types == | |||
<source lang="C"> | |||
typedef struct SceNVSKitActivationData { // size is 0x20 bytes | |||
char magic[4]; // "act\n" | |||
uint32_t issue_no; | |||
uint32_t end_date; | |||
uint32_t start_date; | |||
char cmac_hash[0x10]; | |||
} SceNVSKitActivationData; | |||
</source> | |||
= Config Storage = | |||
Config Storage is a similar storage than [[#NVS|NVS]] but is accessed in a different manner. Whilst [[#NVS|NVS]] is read and written by 32-byte sectors and is physically stored with a sort of history, Config Storage is written by sending scripts from [[Kermit]] to Syscon, and is not really readable but instead affects [[KBL Param#Hardware Info]]. | |||
== Sample scripts == | |||
Below are sample configstorage scripts hardcoded in [[SceSyscon]]: | |||
<source lang="C"> | |||
const char syscon_idu_set_config[0x20] = { | |||
0x1F, 0x54, 0x35, 0x63, 0x38, 0x62, 0x31, 0x64, | |||
0x61, 0x63, 0x62, 0x38, 0x33, 0x36, 0x64, 0x64, | |||
0x36, 0x63, 0x39, 0x39, 0x36, 0x38, 0x65, 0x34, | |||
0x63, 0x30, 0x35, 0x30, 0x61, 0x36, 0x66, 0x35 | |||
}; | |||
const char syscon_idu_set_config2[0x20] = { | |||
0x07, 0x57, 0xA8, 0x01, 0x01, 0x00, 0x0D, 0x00, | |||
0x01, 0x4E, 0x15, 0x48, 0x51, 0xBD, 0x52, 0x2C, | |||
0x4C, 0x83, 0x70, 0xDA, 0x4D, 0xF3, 0x8E, 0x82, | |||
0x6B, 0xD6, 0x34, 0x98, 0x3A, 0xFD, 0xA6, 0x94 | |||
}; | |||
const char syscon_show_set_config[0x20] = { | |||
0x1F, 0x54, 0x66, 0x63, 0x33, 0x39, 0x38, 0x39, | |||
0x30, 0x61, 0x33, 0x32, 0x64, 0x30, 0x66, 0x32, | |||
0x37, 0x36, 0x31, 0x35, 0x62, 0x65, 0x36, 0x65, | |||
0x63, 0x64, 0x63, 0x35, 0x65, 0x32, 0x63, 0x63 | |||
}; | |||
const char syscon_show_set_config2[0x20] = { | |||
0x07, 0x57, 0xA8, 0x01, 0x03, 0x00, 0x10, 0x00, | |||
0x01, 0x4E, 0x15, 0x48, 0xB8, 0x1A, 0x54, 0xD1, | |||
0xF2, 0xA0, 0xD1, 0x05, 0x18, 0xEA, 0x22, 0x09, | |||
0x0A, 0x02, 0x2E, 0xAE, 0x00, 0x08, 0x25, 0xF1 | |||
}; | |||
const char syscon_clear_config[0x20] = { | |||
0x1F, 0x54, 0x65, 0x34, 0x61, 0x65, 0x38, 0x62, | |||
0x37, 0x61, 0x65, 0x38, 0x36, 0x33, 0x32, 0x65, | |||
0x64, 0x64, 0x39, 0x61, 0x61, 0x65, 0x38, 0x38, | |||
0x38, 0x39, 0x66, 0x30, 0x65, 0x65, 0x61, 0x38 | |||
}; | |||
const char syscon_clear_config2[0x20] = { | |||
0x07, 0x57, 0xA8, 0x01, 0x00, 0x00, 0x00, 0x00, | |||
0x01, 0x4E, 0x15, 0x48, 0x88, 0xEA, 0xC7, 0xAD, | |||
0x65, 0xB1, 0x73, 0xC1, 0xCF, 0x48, 0xC7, 0x29, | |||
0x1B, 0x2B, 0x8A, 0x32, 0x89, 0xCF, 0xB3, 0xC1 | |||
}; | |||
</source> | |||
The only actual differences between those scripts are: | |||
* the ascii string: we do not know how it is generated and what it means | |||
* the mode value: | |||
** A8 01 00 00 00 00 = mode clear | |||
** A8 01 01 00 0D 00 = idu mode set | |||
** A8 01 03 00 10 00 = show mode set | |||
== Types == | |||
<source lang="C"> | |||
// TODO | |||
</source> | |||
{| class="wikitable" | |||
|- | |||
! Offset !! Size !! Name !! Sample value !! Comment | |||
|- | |||
| 0 || 1 || ascii_data_size || 0x1F || | |||
|- | |||
| 1 || 1 || ascii_data_flag || 0x54 || | |||
|- | |||
| 2 || 0x1E || ascii_data || || ASCII hexadecimal string so maybe a hash | |||
|- | |||
| 0x20 || 1 || unk_7_data_size || 7 || | |||
|- | |||
| 0x21 || 1 || unk_7_data_flag || || | |||
|- | |||
| 0x22 || 6 || unk_7_data || || | |||
|- | |||
| 0x28 || 1 || unk_1_data_size || 1 || | |||
|- | |||
| 0x29 || 1 || unk_1_data_flag || 0x4E || | |||
|- | |||
| 0x2A || 1 || sha1_hash_size || 0x15 || | |||
|- | |||
| 0x2B || 1 || sha1_hash_flag || 0x48 || | |||
|- | |||
| 0x2C || 0x14 || sha1_hash || || sha1 hash of the previous blocks (data from 0 of size 0x2A) | |||
|} | |||
Config storage scripts have in theory a variable size. It is the concatenation of some blocks where the first byte is the length of the body, followed by the body of variable size. Body structure is always the same: 1 byte representing the flag, followed by data of variable size. | |||
== Usage == | |||
Theory by CelesteBlue (untested): | |||
* 0) Begin Transaction | |||
* 1) Load Script (part 1) | |||
* A) configstorage data is read from SceSyscon memory | |||
* B) configstorage data is sent by SceSyscon to Ernie | |||
* C) Ernie FW checks hash of data and returns xx on success | |||
if success: | |||
* 2) Load Script (part 2) | |||
* A) configstorage data is read from SceSyscon memory | |||
* B) configstorage data is sent by SceSyscon to Ernie using Load | |||
* C) Ernie FW loads data to memory and executes it | |||
*6) Commit Transaction | |||
*7) End Transaction | |||
= Pinout = | |||
[[File:ernie-package.png|600px|Ernie BGA package.]] | |||
A candidate package for this chip is Renesas' [https://www.renesas.com/us/en/package-image/pdf/outdrawing/p121f1-50-bal.pdf P121F1-50-BAL-1]. It has the same size and number of pins. | |||
=== UART === | |||
{| class='wikitable' | |||
! Name || Pin || Description | |||
|- | |||
| CTS0 || J7 || UART0 clear to send | |||
|- | |||
| RTS0 || C6 || UART0 request to send | |||
|- | |||
| TX0 || B6 || UART0 transmit | |||
|- | |||
| RX0 || F11 || UART0 receive | |||
|- | |||
| SW0 || A8 || Switch, see [[UART Console#OLED PSVita UART0 location]] | |||
|} | |||
=== SPI === | |||
Main communication with [[Kermit]]. | |||
{| class='wikitable' | |||
! Name || Pin || Description | |||
|- | |||
| SS || A7 || Slave Select (often active low, output from master) | |||
|- | |||
| MISO || A6 || Master In Slave Out (data output from slave) | |||
|- | |||
| MOSI || C7 || Master Out Slave In (data output from master) | |||
|- | |||
| SCLK || B7 || Serial Clock (output from master) | |||
|} | |||
=== Other === | |||
{| class='wikitable' | |||
! Name || Pin || Description | |||
|- | |||
| ? || C11 || [[UDC]] pin 11 | |||
|- | |||
| ? || F9 || [[UDC]] pin 12 | |||
|- | |||
| ? || G4 || [[UDC]] pin 13 | |||
|- | |||
| ? || G8 || [[SN99057]] pin 38 | |||
|- | |||
| PWR_SW || G6 || Power switch through two transistor buffers | |||
|} | |||
= Versions = | |||
== Hardware Versions == | |||
There are three hardware versions of Ernie: | |||
* NEC 78K0R/Kx3-L: present on early PS Vita prototypes (never seen) | |||
* NEC 78K0R/Kx3: present on Fat PS Vita and PS TV models, including some prototypes such as DEM-3000L | |||
* Renesas RL78/G13: present on Slim PS Vita models | |||
=== NEC 78K0R/Kx3-L === | |||
Never seen yet but exists according to Ernie update packages. | |||
=== NEC 78K0R/Kx3 === | |||
NEC D79F0109 (78K0R/KH3, 121 pin) | |||
Device Name : D79F0109 | |||
Other Device Name : SK0RT02N200GV120 (on DEM-3000L and PCH-1000) | |||
Label: | |||
<pre> | |||
Model <- always D79F0109 | |||
Revision <- on DEM-3000H: ES1.0, blank on others | |||
Build <- XXYYZZWWW <- XX: year, YY: week, ZZ: 2 letters (unknown usage), WWW: serial number | |||
Manufacturing country <- always "MALAYSIA" | |||
</pre> | |||
=== Renesas RL78/G13 === | |||
Renesas R5F1ZCRK (RL78/G13, 121 pin) | |||
<pre> | |||
R5F1ZCRKABG#U0 | |||
R5 Renesas MCU | |||
F Flash | |||
1 RL78 | |||
Z Customer specific | |||
C Product group | |||
R 121-pin | |||
K 384KB | |||
A Consumer grade | |||
BG VFBGA 0.4mm | |||
#U0 Tray*2 | |||
</pre> | |||
<pre> | |||
Device Name : R5F1ZCRK | |||
Device Code : 10 00 06 | |||
Firmware Version : V3.03 | |||
Code Flash 1 (Address : 0x00000000, Size : 384 K, Erase Size : 1 K) | |||
Data Flash 1 (Address : 0x000F1000, Size : 8 K, Erase Size : 1 K) | |||
</pre> | |||
Label: | |||
<pre> | |||
(C) XXXX <- Year | |||
Revision <- A0xxx SCEI | |||
Build <- XXYYZZWWW <- XX: year, YY: week, ZZ: 2 letters (unknown usage), WWW: serial number | |||
Unknown data | |||
</pre> | |||
== Block sizes == | |||
Ernie flash memory is erasable in blocks. Size of one block in bytes depends on the hardware version: | |||
* NEC 78K0R/Kx3-L: 0x800 | |||
* NEC 78K0R/Kx3: 0x400 | |||
* Renesas RL78/G13: 0x400 | |||
See also [https://playstationdev.wiki/psvitadevwiki/index.php?title=Ernie]. | |||
== Software Versions == | |||
See also [https://playstationdev.wiki/psvitadevwiki/index.php?title=System_Controller_Firmware]. | |||
Ernie firmware can be partly updated and downgraded with software updates embedded in PUP. | |||
Ernie firmware is dependant of the hardware version and detects it based on [[KBL Param#Hardware_Info|Hardware Info]]. | |||
=== Examples === | |||
With DevKit connected, <code>psp2ctrl info</code> queries return the following results: | |||
DEM-3000H running FW 0.990: | |||
<source>SysConVersion: 591105</source> -> converted to hexadecimal: 0x00090501 -> 0.9.5.1 | |||
PDEL-1001 running FW 1.692: | |||
<source>SCVersion: 0.9.2.4</source> | |||
PDEL-1001 running FW 3.600-3.680: | |||
<source>SCVersion: 1.0.3.6</source> | |||
=== Downgrade === | |||
Syscon is downgradable on DEM/PDEL/PTEL/QAF units. It might also be downgraded on retail when using a downgrade enabler like modoru. | |||
= Firmware = | |||
See [[Ernie Firmware]] | |||
[[Category:Devices]] | [[Category:Devices]] |
Latest revision as of 18:08, 19 May 2024
Ernie is the codename for the Syscon chip. The Syscon is for exemple responsible for handling button input (including power button), reading/writing to non-volatile storage (NVS) for storing system flags (mostly encrypted and signed). For example IDU flag is stored in NVS. Syscon is also responsible for maintaining the physical address to the resume buffer during Suspend. Communication between Kermit and Syscon is mainly through SPI (see SceSyscon) but there are also some GPIO pins connecting the two. The chip model is NEC/Renesas uPD79F0109
and is likely custom designed for Sony.
See also: Ernie Secure
Boot Process
The following is logged from boot. The timestamp is in seconds (the starting time is irrelevant). The arrow at the start indicates direction: '>' means Kermit to Syscon (MOSI) and '<' means Syscon to Kermit (MISO). Then there is a 2 byte command id or response code, followed by a flag byte (response only), the payload, a checksum byte, and an (response only) unknown byte. Please note that the packets are listed in transfer order but this may not represent the logical order of the packets. It is currently unknown what the logical order should be, but one can guess that a response is "close to" a request.
First some version information seems to be sent from Syscon to Kermit. This is same for cold boot and resume boot. The last response indicates the type of boot where 0xFF80 is resume and 0xFF14 is regular boot.
< [2.048118000000000] 0x0004, flags=00, payload=[0D 06 00 01 | ....], chk=0xE1, unk=0x00 > [2.048118000000000] 0x0001, payload=[ | ], chk=0xFD < [2.048659583333333] 0x0004, flags=00, payload=[00 60 40 00 | .`@.], chk=0x55, unk=0x00 > [2.048659583333333] 0x0005, payload=[ | ], chk=0xF9 < [2.049330083333333] 0x0004, flags=00, payload=[32 30 31 32 31 31 30 38 31 37 30 34 | 201211081704], chk=0x92, unk=0x00 > [2.049330083333333] 0x0002, payload=[ | ], chk=0xFC < [2.054004333333333] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x30 > [2.054004333333333] 0x0080, payload=[12 00 | ..], chk=0x6A < [2.058172916666666] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x30 > [2.058172916666666] 0x0000, payload=[ | ], chk=0xFE < [2.062716333333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x30 > [2.062716333333333] 0x0080, payload=[12 00 | ..], chk=0x6A < [2.111457750000000] 0x0004, flags=00, payload=[14 FF | ..], chk=0xE4, unk=0x32
Next some encrypted session is established. A 8 byte nonce is sent from Syscon (it appears random for each boot, cold or warm). Encrypted data from this point on always differs each boot.
> [2.111457750000000] 0x0010, payload=[ | ], chk=0xEE < [2.133389000000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0xFF > [2.133389000000000] 0x00A0, payload=[30 00 00 0B 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xFB < [2.150567250000000] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0xFF > [2.150567250000000] 0x0000, payload=[ | ], chk=0xFE < [2.155149500000000] 0x0024, flags=00, payload=[30 01 00 0B 00 00 00 00 A4 B0 EF 23 D6 9A 3A 06 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0..........#..:.........................], chk=0x5F, unk=0x00 > [2.155149500000000] 0x00A0, payload=[30 00 00 0B 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xFB < [2.163572000000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x01 > [2.163572000000000] 0x00A0, payload=[30 02 00 0B 01 00 00 00 6C 7F E0 79 AA 03 4B B0 96 B7 42 F0 BC F8 62 7A 35 27 53 68 3D 0D ED A7 13 F2 32 77 46 2D 54 F8 | 0.......l..y..K...B...bz5'Sh=.....2wF-T.], chk=0x9B < [2.189271166666667] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x01 > [2.189271166666667] 0x0000, payload=[ | ], chk=0xFE < [2.193866583333334] 0x0024, flags=00, payload=[30 03 00 0B 00 00 00 00 7A 44 6E C8 F5 FA 35 CB 9B E9 E6 A0 B6 5C 85 1D FB A8 89 5C 9C 04 0B 29 34 59 55 EB 1D 98 AB 83 | 0.......zDn...5......\.....\...)4YU.....], chk=0xC6, unk=0x00 > [2.193866583333334] 0x00A0, payload=[30 02 00 0B 01 00 00 00 6C 7F E0 79 AA 03 4B B0 96 B7 42 F0 BC F8 62 7A 35 27 53 68 3D 0D ED A7 13 F2 32 77 46 2D 54 F8 | 0.......l..y..K...B...bz5'Sh=.....2wF-T.], chk=0x9B
Some more data is exchanged. Up until this point all the plaintext payloads appear to be the same from coldboot and warmboot.
< [2.202246333333334] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 > [2.202246333333334] 0x088E, payload=[01 22 | ."], chk=0x43 < [2.206411750000000] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x03 > [2.206411750000000] 0x0000, payload=[ | ], chk=0xFE < [2.217062666666667] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 > [2.217062666666667] 0x0000, payload=[ | ], chk=0xFE < [2.221620916666667] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 > [2.221620916666667] 0x088E, payload=[01 22 | ."], chk=0x43 < [2.229805500000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 > [2.229805500000000] 0x1082, payload=[80 04 08 | ...], chk=0xDD < [2.233887583333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 > [2.233887583333333] 0x0000, payload=[ | ], chk=0xFE < [2.238363416666667] 0x0024, flags=00, payload=[FF FF FF FF 01 FF FF FF | ........], chk=0xD7, unk=0x44 > [2.238363416666667] 0x1082, payload=[80 04 08 | ...], chk=0xDD < [2.246473916666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0xFF
Now, there appears to be a branch. The next sequence only shows up for cold boots.
> [2.246473916666667] 0x1082, payload=[A0 04 01 | ...], chk=0xC4 < [2.250555000000000] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0xFF > [2.250555000000000] 0x0000, payload=[ | ], chk=0xFE < [2.255030833333334] 0x0024, flags=00, payload=[FF | .], chk=0xD9, unk=0x00 > [2.255030833333334] 0x1082, payload=[A0 04 01 | ...], chk=0xC4 < [2.259176583333333] 0x0004, flags=00, payload=[01 01 13 00 | ....], chk=0xE0, unk=0xFF > [2.259176583333333] 0x1100, payload=[ | ], chk=0xED < [2.263720583333333] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x01 > [2.263720583333333] 0x00D0, payload=[30 00 00 0F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xC7 < [2.267827000000000] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x01 > [2.267827000000000] 0x0000, payload=[ | ], chk=0xFE < [2.278339666666667] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x01 > [2.278339666666667] 0x0000, payload=[ | ], chk=0xFE < [2.282830833333333] 0x0024, flags=00, payload=[30 01 00 0F 00 00 00 00 E1 CA 65 96 BB 7E 81 7A 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.........e..~.z........................], chk=0x97, unk=0x00 > [2.282830833333333] 0x00D0, payload=[30 00 00 0F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xC7 < [2.291023500000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x01 > [2.291023500000000] 0x00D0, payload=[30 02 00 0F 01 00 00 00 4E D7 C0 7C D5 E8 BB D7 3E 9E 43 7B B2 E3 4D 81 23 C8 C4 BF B8 4D 9B 25 0A 3D C7 45 E6 0D 23 43 | 0.......N..|....>.C{..M.#....M.%.=.E..#C], chk=0x38 < [2.295129250000000] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x01 > [2.295129250000000] 0x0000, payload=[ | ], chk=0xFE < [2.305641750000000] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x01 > [2.305641750000000] 0x0000, payload=[ | ], chk=0xFE < [2.310132916666667] 0x0024, flags=00, payload=[30 03 00 0F 00 00 00 00 5B 3E 5C 5F 11 F9 E4 6A 85 0D 1E 06 9E F9 33 25 9B 95 55 21 39 48 FC 55 C7 BF A7 E4 32 AD FC 65 | 0.......[>\_...j......3%..U!9H.U....2..e], chk=0x55, unk=0x00 > [2.310132916666667] 0x00D0, payload=[30 02 00 0F 01 00 00 00 4E D7 C0 7C D5 E8 BB D7 3E 9E 43 7B B2 E3 4D 81 23 C8 C4 BF B8 4D 9B 25 0A 3D C7 45 E6 0D 23 43 | 0.......N..|....>.C{..M.#....M.%.=.E..#C], chk=0x38 < [2.318358166666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 > [2.318358166666667] 0x00D0, payload=[30 04 00 0F 00 00 00 00 52 8D 6D BC 90 C9 00 EE FA CA 47 63 10 D1 4A E5 5A FD BB 91 3A 6C DA EF 64 CA 71 01 4A A9 D5 31 | 0.......R.m.......Gc..J.Z...:l..d.q.J..1], chk=0x4B < [2.322464250000000] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x03 > [2.322464250000000] 0x0000, payload=[ | ], chk=0xFE < [2.332976833333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 > [2.332976833333333] 0x0000, payload=[ | ], chk=0xFE < [2.337468000000000] 0x0024, flags=00, payload=[30 05 00 0F 00 00 00 00 52 8D 6D BC 90 C9 00 EE FA CA 47 63 10 D1 4A E5 5A FD BB 91 3A 6C DA EF 64 CA 71 01 4A A9 D5 31 | 0.......R.m.......Gc..J.Z...:l..d.q.J..1], chk=0xF5, unk=0x00 > [2.337468000000000] 0x00D0, payload=[30 04 00 0F 00 00 00 00 52 8D 6D BC 90 C9 00 EE FA CA 47 63 10 D1 4A E5 5A FD BB 91 3A 6C DA EF 64 CA 71 01 4A A9 D5 31 | 0.......R.m.......Gc..J.Z...:l..d.q.J..1], chk=0x4B < [2.345696333333333] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x05
Then another set of shared sequence. Some differences in the warmboot responses though. On line 18,
FF BF FF 74
becomes
FF FF FF 74
. On line 12, the
00 00 00 00
becomes the physical address of the resume context buffer. Example:
F0 1E 1F 41
> [2.345696333333333] 0x00D2, payload=[20 7A 3E 7B 31 DE FC 3A 11 5F 64 E7 AB A4 EC 17 | .z>{1..:._d.....], chk=0x77 < [2.349790333333333] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x05 > [2.349790333333333] 0x0000, payload=[ | ], chk=0xFE < [2.360448916666666] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x05 > [2.360448916666666] 0x0000, payload=[ | ], chk=0xFE < [2.364930250000000] 0x0024, flags=00, payload=[9D 0B BC 4D BA 66 40 2C 63 BE F3 79 D0 31 26 1E 47 3A 64 DE 68 2F AE E2 8A B6 F0 27 37 46 89 16 0E 71 04 FA BF C9 4A A1 DF 4B EF D3 3D 0D 39 CD | ...M.f@,c..y.1&.G:d.h/.....'7F...q....J..K..=.9.], chk=0x11, unk=0x00 > [2.364930250000000] 0x00D2, payload=[20 7A 3E 7B 31 DE FC 3A 11 5F 64 E7 AB A4 EC 17 | .z>{1..:._d.....], chk=0x77 < [2.373236666666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x0B > [2.373236666666667] 0x0090, payload=[0C 00 04 | ...], chk=0x5B < [2.377318583333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x0B > [2.377318583333333] 0x0000, payload=[ | ], chk=0xFE < [2.381794416666667] 0x0024, flags=00, payload=[00 00 00 00 | ....], chk=0xD5, unk=0x66 > [2.381794416666667] 0x0090, payload=[0C 00 04 | ...], chk=0x5B < [2.385879750000000] 0x0004, flags=00, payload=[40 00 | @.], chk=0xB7, unk=0x00 > [2.385879750000000] 0x0800, payload=[ | ], chk=0xF6 < [2.386382583333333] 0x0004, flags=00, payload=[FF BF FF 74 | ...t], chk=0xC4, unk=0x66 > [2.386382583333333] 0x0100, payload=[ | ], chk=0xFD < [2.386871833333333] 0x0004, flags=00, payload=[10 00 00 00 | ....], chk=0xE5, unk=0x66 > [2.386871833333333] 0x0003, payload=[ | ], chk=0xFB < [2.387380083333333] 0x0000, flags=3F, payload=[ | ], chk=0xBE, unk=0x00 > [2.387380083333333] 0x0006, payload=[ | ], chk=0xF8 < [2.481997666666667] 0x0000, flags=80, payload=[ | ], chk=0x7D, unk=0x00 > [2.481986333333333] 0x00D2, payload=[30 14 F4 B8 84 89 81 AB 3D 07 66 DE AE B6 D3 24 | 0.......=.f....$], chk=0x10 < [2.514678500000000] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0x00 > [2.514678500000000] 0x0000, payload=[ | ], chk=0xFE < [2.519163916666667] 0x0020, flags=00, payload=[1A 1F BC 74 AA 16 59 D6 5C E7 FF 5B E0 85 B2 C8 39 2D D6 95 98 2F B7 4B 71 64 34 D7 8D 2C 94 A1 91 CB 73 D7 8D E1 D0 07 E6 1E 0F DA E7 51 BC 69 | ...t..Y.\..[....9-.../.Kqd4..,....s..........Q.i], chk=0x3C, unk=0x00 > [2.519163916666667] 0x00D2, payload=[30 14 F4 B8 84 89 81 AB 3D 07 66 DE AE B6 D3 24 | 0.......=.f....$], chk=0x10 < [2.527551416666667] 0x0000, flags=80, payload=[ | ], chk=0x7D, unk=0x1F > [2.527540083333333] 0x088E, payload=[02 29 | .)], chk=0x3B < [2.531619416666667] 0x0000, flags=00, payload=[ | ], chk=0xFD, unk=0x1F > [2.531619416666667] 0x0000, payload=[ | ], chk=0xFE < [2.542392416666666] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0x1F > [2.542392416666666] 0x0000, payload=[ | ], chk=0xFE < [2.546867583333333] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0x1F > [2.546867583333333] 0x088E, payload=[02 29 | .)], chk=0x3B
Then, the two boot paths diverge completely (also note the time jump). It is suspected that at this point the kernel is started up on coldboot, and the kernel resumes for warmboot. For cold boot only, we see the beginning init sequence again, which is likely done in SceSyscon.
< [3.322105750000000] 0x0000, flags=00, payload=[0D 06 00 01 | ....], chk=0xE5, unk=0x16 > [3.322105750000000] 0x0001, payload=[ | ], chk=0xFD < [3.326563916666667] 0x0000, flags=00, payload=[32 30 31 32 31 31 30 38 31 37 30 34 | 201211081704], chk=0x96, unk=0x85 > [3.326552583333333] 0x0002, payload=[ | ], chk=0xFC < [3.331090666666667] 0x0000, flags=80, payload=[ | ], chk=0x7D, unk=0x30 > [3.331079333333333] 0x0080, payload=[12 00 | ..], chk=0x6A < [3.331576333333333] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0x30 > [3.331576333333333] 0x0080, payload=[12 00 | ..], chk=0x6A < [3.332068833333333] 0x0000, flags=00, payload=[10 00 00 00 | ....], chk=0xE9, unk=0x31 > [3.332068833333333] 0x0004, payload=[ | ], chk=0xFA < [3.332541666666667] 0x0000, flags=00, payload=[00 FF 04 00 | ....], chk=0xF6, unk=0x31 > [3.332541666666667] 0x0103, payload=[ | ], chk=0xFA < [3.336980333333333] 0x0000, flags=00, payload=[10 00 00 00 | ....], chk=0xE9, unk=0x31 > [3.336980333333333] 0x0003, payload=[ | ], chk=0xFB ...
Packet checksum
The checksum byte of the packet is calculated as the binary negation of the sum of all the bytes of the packet (including the 2 bytes of the command id and the byte for the length). The checksum calculation can be implemented as follows:
void syscon_calc_checksum(unsigned char packet[32], int length) { int i; unsigned char hash = 0; for (i = 0; i < 3 + length; i++) hash += packet[i]; packet[3 + length] = ~hash; }
Commands
Commands are listed in the order seen in cold boot. The numbers in the captured packets indicate the assumed order with some unused packets filtered out (they appear to be resent). The ordering and grouping are assumed and may contain errors.
CMD 0x0001 - sceSysconGetErnieVersion
Gets version of the current installed Ernie firmware. Can also be seen in the packet header in Syscon Update. Also sent at kernel boot.
SEND 1 > [2.881037083333333] 0x0001, payload=[ | ], chk=0xFD RESP 1 < [2.881037083333333] 0x0004, flags=00, payload=[0D 06 00 01 | ....], chk=0xE1, unk=0x71
SEND 23 > [4.167151583333333] 0x0001, payload=[ | ], chk=0xFD RESP 23 < [4.167151583333333] 0x0000, flags=00, payload=[0D 06 00 01 | ....], chk=0xE5, unk=0x32
CMD 0x0005 - sceSysconGetHardwareInfo
SEND 2 > [2.881578833333333] 0x0005, payload=[ | ], chk=0xF9 RESP 2 < [2.881578833333333] 0x0004, flags=00, payload=[00 60 40 00 | .`@.], chk=0x55, unk=0x71
CMD 0x0002 - sceSysconGetTimeStamp
Gets Ernie firmware timestamp. Also sent at kernel boot.
SEND 3 > [2.882249083333333] 0x0002, payload=[ | ], chk=0xFC RESP 3 < [2.882249083333333] 0x0004, flags=00, payload=[32 30 31 32 31 31 30 38 31 37 30 34 | 201211081704], chk=0x92, unk=0x00
SEND 24 > [4.171598000000000] 0x0002, payload=[ | ], chk=0xFC RESP 24 < [4.171598000000000] 0x0000, flags=00, payload=[32 30 31 32 31 31 30 38 31 37 30 34 | 201211081704], chk=0x96, unk=0xF7
CMD 0x0080
Unknown. Sends data 0x0012 on FW 3.60. Does not get return data. Also sent at kernel boot.
SEND 4 > [2.895635416666666] 0x0080, payload=[12 00 | ..], chk=0x6A RESP 4 < [2.886923416666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x30 RESP 4 < [2.891092083333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x30 RESP 4 < [2.895635416666666] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x30
SEND 25 > [4.176620750000000] 0x0080, payload=[12 00 | ..], chk=0x6A RESP 25 < [4.176123750000000] 0x0000, flags=80, payload=[ | ], chk=0x7D, unk=0x30 RESP 25 < [4.176620750000000] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0x30
CMD 0x0010 - sceSysconGetWakeupFactor
See Wakeup Factor.
Boot type indicator. 0xFF14 on cold boot. 0xFF80 on resume boot.
SEND 5 > [2.950546416666667] 0x0010, payload=[ | ], chk=0xEE RESP 5 < [2.950546416666667] 0x0004, flags=00, payload=[14 FF | ..], chk=0xE4, unk=0x32
CMD 0x00A0 - Handshake
Runs twice. Appears to contain a 8 byte inner header. First packet sends all zeros and gets back a 8 byte random response. This is likely a nonce or challenge. This likely establishes an encrypted session. Encrypted data differs on each boot. There does not appear to be data transferred using the established session.
SEND 6 > [2.994470666666667] 0x00A0, payload=[30 00 00 0B 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xFB RESP 6 < [2.972471333333333] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0xFF RESP 6 < [2.989889500000000] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0xFF RESP 6 < [2.994470666666667] 0x0024, flags=00, payload=[30 01 00 0B 00 00 00 00 CA 71 11 BA 86 87 EF 0D 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0........q..............................], chk=0x66, unk=0x00 SEND 7 > [3.033187750000000] 0x00A0, payload=[30 02 00 0B 01 00 00 00 92 45 B4 A5 49 15 CE F2 39 0E 9E 4C BF FA 19 E6 5D CF BA 5A 6E C3 7C ED 2A 6D 4E 79 84 28 1C 2A | 0........E..I...9..L....]..Zn.|.*mNy.(.*], chk=0x97 RESP 7 < [3.002893083333333] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x01 RESP 7 < [3.028592333333334] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x01 RESP 7 < [3.033187750000000] 0x0024, flags=00, payload=[30 03 00 0B 00 00 00 00 12 77 A5 98 67 F7 38 9B B4 54 48 FE 84 82 CF 84 41 42 87 A2 EA D1 CF 9C 5B D1 2A 3F 1E 50 B9 3D | 0........w..g.8..TH.....AB......[.*?.P.=], chk=0x0A, unk=0x00
CMD 0x088E - sceSysconCtrlVoltage
Controls voltage. Sends value 0x2201 on FW 3.60 and does not get any response.
SEND 8 > [3.061354583333333] 0x088E, payload=[01 22 | ."], chk=0x43 RESP 8 < [3.041713500000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 RESP 8 < [3.046148250000000] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x03 RESP 8 < [3.056796250000000] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 RESP 8 < [3.061354583333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03
CMD 0x1082 - NVS Read
Get data from NVS. 2-byte offset followed by 1 byte length. For example used to fetch boot-time flags, like Update Mode.
Get Qaf Token area: SEND 9 > [3.078212500000000] 0x1082, payload=[80 04 08 | ...], chk=0xDD RESP 9 < [3.069790250000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 RESP 9 < [3.073736583333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 RESP 9 < [3.078212500000000] 0x0024, flags=00, payload=[FF FF FF FF 01 FF FF FF | ........], chk=0xD7, unk=0x77 Get Update Mode: SEND 10 > [3.094879833333333] 0x1082, payload=[A0 04 01 | ...], chk=0xC4 RESP 10 < [3.086322916666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0xFF RESP 10 < [3.090404000000000] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0xFF RESP 10 < [3.094879833333333] 0x0024, flags=00, payload=[FF | .], chk=0xD9, unk=0x00
CMD 0x1100 - sceSysconGetErnieDLVersion
Gets Ernie DownLoader Version i.e. version of Ernie firmware.
SEND 11 > [3.099025500000000] 0x1100, payload=[ | ], chk=0xED RESP 11 < [3.099025500000000] 0x0004, flags=00, payload=[01 01 13 00 | ....], chk=0xE0, unk=0xFF
CMD 0x00D0 - Handshake before SNVS RW
Some encrypted transfer that looks close to Syscon#CMD 0x00A0 in format. Different on each boot.
SEND 12 > [3.122679833333333] 0x00D0, payload=[30 00 00 0F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.......................................], chk=0xC7 RESP 12 < [3.103569583333333] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x01 RESP 12 < [3.107676166666667] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x01 RESP 12 < [3.118188666666667] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x01 RESP 12 < [3.122679833333333] 0x0024, flags=00, payload=[30 01 00 0F 00 00 00 00 9F CC 4A 69 73 E9 C0 5A 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 | 0.........Jis..Z........................], chk=0xDD, unk=0x00 SEND 13 > [3.150031916666667] 0x00D0, payload=[30 02 00 0F 01 00 00 00 98 6D 3A 1E C5 B1 E9 AF 54 65 55 91 3B DF 2B A8 0F AD B0 73 A0 A2 0F EE 5D 0A AF 41 A5 6D 32 20 | 0........m:.....TeU.;.+....s....]..A.m2.], chk=0xF4 RESP 13 < [3.130872500000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x01 RESP 13 < [3.134978166666667] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x01 RESP 13 < [3.145539833333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x01 RESP 13 < [3.150031916666667] 0x0024, flags=00, payload=[30 03 00 0F 00 00 00 00 F5 19 C0 67 09 80 C6 DB 58 8D FB E1 86 22 D1 00 DA BB D2 AF AA 51 F9 57 7C 56 92 0A 94 D6 60 4D | 0..........g....X....".......Q.W|V....`M], chk=0xF0, unk=0x00 SEND 14 > [3.177452416666667] 0x00D0, payload=[30 04 00 0F 00 00 00 00 87 4E 59 41 22 98 F8 62 BD B4 C8 4F 4C 0A 81 90 47 1E 1E 70 D6 51 57 42 E5 EC 07 A2 D4 CF E5 02 | 0........NYA"..b...OL...G..p.QWB........], chk=0x9A RESP 14 < [3.158257166666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x03 RESP 14 < [3.162363250000000] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x03 RESP 14 < [3.172875666666667] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x03 RESP 14 < [3.177452416666667] 0x0024, flags=00, payload=[30 05 00 0F 00 00 00 00 87 4E 59 41 22 98 F8 62 BD B4 C8 4F 4C 0A 81 90 47 1E 1E 70 D6 51 57 42 E5 EC 07 A2 D4 CF E5 02 | 0........NYA"..b...OL...G..p.QWB........], chk=0x44, unk=0x00
CMD 0x00D2 - SNVS RW
This command is used twice during boot and also quite often after boot. Data is different on each boot. Encrypted session using key from handshake above. Second transaction is the firmware version data written during the update process.
SEND 15 > [3.204733083333333] 0x00D2, payload=[32 78 88 CF 3E 63 56 19 75 3A 0A 2D F3 49 63 E2 | 2x..>cV.u:.-.Ic.], chk=0xA4 RESP 15 < [3.185595250000000] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x05 RESP 15 < [3.189740333333333] 0x0004, flags=00, payload=[ | ], chk=0xF9, unk=0x05 RESP 15 < [3.200251666666666] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x05 RESP 15 < [3.204733083333333] 0x0024, flags=00, payload=[D3 57 9B F2 A2 45 E2 7A 2A FC 84 12 97 8E 23 5F C8 AB FB 58 97 EC DE 20 94 0A 78 28 C6 EE C5 45 18 29 00 F4 56 22 53 AF 24 47 8E FF B1 5C DA 2F | .W...E.z*.....#_...X......x(...E.)..V"S.$G...\./], chk=0x4C, unk=0xFF
SEND 21 > [3.359112250000000] 0x00D2, payload=[1C 0B 9E FF FB 68 90 4B FD C2 05 CD D8 67 4D D0 | .....h.K.....gM.], chk=0x2D RESP 21 < [3.321934500000000] 0x0000, flags=80, payload=[ | ], chk=0x7D, unk=0x00 RESP 21 < [3.354626666666667] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0x00 RESP 21 < [3.359112250000000] 0x0020, flags=00, payload=[6C B4 26 F3 CD 32 D3 3E 6F 80 F2 0F 68 F7 E2 96 58 DB 2F BB AB A6 98 DD 26 14 DD 61 12 E4 55 BA BB 32 1D 1F 75 D5 D1 4C 7E 4A 19 42 E5 B0 C6 AB | l.&..2.>o...h...X./.....&..a..U..2..u..L~J.B....], chk=0x84, unk=0xFF
CMD 0x0090 - sceSysconReadScratchPad
This command reads data from Ernie Scratch Pad. This is the inverse of command 0x91.
This is used for example to fetch the saved resume context buffer physical address. Kernel sets this before suspending and this value is passed to the resume function. See Suspend. The format is 2 byte offset and 1 byte length.
SEND 16 > [3.221743166666667] 0x0090, payload=[0C 00 04 | ...], chk=0x5B RESP 16 < [3.213273166666667] 0x0004, flags=80, payload=[ | ], chk=0x79, unk=0x57 RESP 16 < [3.217267333333333] 0x0024, flags=00, payload=[ | ], chk=0xD9, unk=0x57 RESP 16 < [3.221743166666667] 0x0024, flags=00, payload=[F0 0E 1F 41 | ...A], chk=0x77, unk=0x45
CMD 0x0091 - sceSysconWriteScratchPad
This command writes data to Ernie Scratch Pad. This is the inverse of command 0x90.
CMD 0x0800 - SceSysconForDriver_A2FE9BF9
See KBL Param.
SEND 17 > [3.225828583333334] 0x0800, payload=[ | ], chk=0xF6 RESP 17 < [3.225828583333334] 0x0004, flags=00, payload=[40 00 | @.], chk=0xB7, unk=0x41
CMD 0x0100 - sceSysconGetControlsInfo
See Boot Controls Info.
SEND 18 > [3.226331500000000] 0x0100, payload=[ | ], chk=0xFD RESP 18 < [3.226331500000000] 0x0004, flags=00, payload=[FF BF FF 74 | ...t], chk=0xC4, unk=0x45
CMD 0x0003 - sceSysconGetSleepFactor
See Sleep Factor.
SEND 19 > [3.226820750000000] 0x0003, payload=[ | ], chk=0xFB RESP 19 < [3.226820750000000] 0x0004, flags=00, payload=[10 00 00 00 | ....], chk=0xE5, unk=0x45
CMD 0x0006 - sceSysconGetHardwareInfo2
See Hardware Info 2.
SEND 20 > [3.227328833333333] 0x0006, payload=[ | ], chk=0xF8 RESP 20 < [3.227328833333333] 0x0000, flags=3F, payload=[ | ], chk=0xBE, unk=0x00
CMD 0x088E - sceSysconCtrlVoltage
Last command sent before a time-jump (likely indicating completion of early-boot).
SEND 22 > [3.386554833333333] 0x088E, payload=[02 29 | .)], chk=0x3B RESP 22 < [3.367488416666667] 0x0000, flags=80, payload=[ | ], chk=0x7D, unk=0xB4 RESP 22 < [3.371567833333333] 0x0000, flags=00, payload=[ | ], chk=0xFD, unk=0xB4 RESP 22 < [3.382079833333334] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0xB4 RESP 22 < [3.386554833333333] 0x0020, flags=00, payload=[ | ], chk=0xDD, unk=0xB4
CMD 0x0004
Unknown. Likely happens after initial boot.
SEND 26 > [4.177113250000000] 0x0004, payload=[ | ], chk=0xFA RESP 26 < [4.177113250000000] 0x0000, flags=00, payload=[10 00 00 00 | ....], chk=0xE9, unk=0x31
CMD 0x0103 - sceSysconGetMultiCnInfo
Likely happens after initial boot.
SEND 27 > [4.177586083333333] 0x0103, payload=[ | ], chk=0xFA RESP 27 < [4.177586083333333] 0x0000, flags=00, payload=[00 FF 04 00 | ....], chk=0xF6, unk=0x31
Syscon Scratch Pad
Offset | Size | Name | Comment | Used by |
---|---|---|---|---|
0x0 | 8 | unknown | ||
0x8 | 4 | Syscon power on time | ex on DevKit: 0xA, 0x16, 0x1F, 0x24. ex on retail: 0x01BC0CD0, 0x05AC1AF7, 0x80000269 | SceRtc#sceRtcSetCurrentTickForDriver |
0xC | 4 | Resume context physical address | Set on retail. Not set on DevKit. ex: 0x411F1EF0 | second_loader |
0x10 | 5 | Current Tick | Set on retail and DevKit. Stored in microseconds since 01/01/0001 divided by 2^19. | SceRtc#sceRtcSetCurrentTickForDriver |
0x15 | 3 | Padding of Current Tick | ||
0x18 | 5 | Current Secure Tick | Set on retail. Not set on DevKit. | SceRtc#sceRtcSetCurrentSecureTickForDriver |
0x1D | 5 | Current Network Tick | Always a bit earlier than Current Tick and Current Secure Tick. | SceRtc#sceRtcSetCurrentNetworkTickForDriver |
0x22 | 5 | Current ?Debug Secure?/?Tool Secure? Tick | Set on DevKit. Not set on retail. | SceRtc#sceRtcGetCurrentToolSecureTickForDriver |
0x27 | 5 | Current Aux Tick | SceRtc#sceRtcSetCurrentAuxTickForDriver | |
0x2C | 5 | Current Debug Network Tick | SceRtc#sceRtcSetCurrentDebugNetworkTickForDriver | |
0x31 | 0x8F | unknown | Maybe reserved. Probably unused. | |
0xE0 | 0x20 | CP DIP Switches | Set on DevKit having a CP. Hence not set on Retail nor TestKit. | ?secure_kernel? before system suspend, second_loader after system resume |
Types
typedef struct SceSysconRtcTick { // size is 5 bytes uint8_t tick[5]; } SceSysconRtcTick; typedef struct SceSysconScratchPad { // size is 0x100 bytes uint8_t unk_0[8]; SceUInt32 powerOnTime; void *resumeContextPA; SceRtcSysconTick currentTick; uint8_t padding[3]; SceSysconRtcTick currentSecureTick; SceSysconRtcTick currentNetworkTick; SceSysconRtcTick unk_0x22; SceSysconRtcTick currentAuxTick; SceSysconRtcTick currentDebugNetworkTick; uint8_t reserved[0x8F]; SceDIPSW dipsw; } SceSysconScratchPad;
NVS
Ernie Non-volatile storage (NVS) is a persistent storage allocated on Ernie Data Flash that is used by PS Vita OS for data required at boot time. Indeed, reading NVS requires no driver except the driver to communicate with Syscon, whilst reading PS Vita eMMC requires its AES-XTS decryption.
Not every NVS sector is directly readable from Kermit: the first sectors are part of SNVS (Secure NVS) which means that they are XTS-encrypted and must be accessed through a Secure handshake.
NVS actual size is 0xBA0 bytes on new Syscon hardware revisions and 0xC20 on old. However, only 0xB60 bytes are accessible from Kermit on System Software 3.600.011 and more recent. The hidden area is probably used internally by Syscon as it is not blanked nor 0xFFed.
On FW 3.60, NVS size accessible from Kermit is 0xB60 bytes:
- Area from 0 to 0x3FF is named Ernie Secure#SNVS. It has an additional level of encryption. It cannot be read using SceSblSsMgr#sceSblNvsReadForKernel nor written using SceSblSsMgr#sceSblNvsWriteForKernel. This area is handled by Secure Modules.
- Area from 0x400 to 0x75F is handled by Non-secure Kernel SceSblSsMgr module.
- Area from 0x760 to 0xB5F is reserved for Test and Tool consoles. However this area seems unused.
- Area from 0xB60 to the end of NVS is not accessible from Kermit.
Offset | Size | Name | Comment | Used by |
---|---|---|---|---|
0 | 0x400 | SNVS | See Ernie Secure#SNVS. | |
0x400 | 0x80 | Qaf Token | second_loader | |
0x480 | 0x1 | Qaf Token Flag | 1 when Qaf Token is not set (FFed), 0 when Qaf Token is set | second_loader |
0x481 | 0x1 | Extra UART Flag | 0xFF - extra UART disabled, 0x00 - extra UART enabled, 0x01 - extra UART enabled only when Jig dongle is connected | second_loader |
0x482 | 0x1 | Unknown | SceSblSsMgr#sceSblSsGetNvsDataForDriver, SceSblSsMgr#sceSblSsSetNvsDataForDriver | |
0x483 | 0x1 | Safe Mode Flags | 0xFF - not safe mode, 1, 3, 5, 9, 0x11 - safemode type | SceSblSsMgr#sceSblSsGetNvsDataForDriver, SceSblSsMgr#sceSblSsSetNvsDataForDriver, second_loader, set by SceShellSvc#sceShellUtilRequestRebootWithError, read by SceSafeMode |
0x484 | 0x1 | KervResult /KervDiagResultFlag |
Factory test preCheckFactTest
| |
0x485 | 0x1 | Unknown | ||
0x486 | 0x1 | MCEmu Flag (use internal ux0 ) |
0xFF on FAT - no internal storage or on PS TV or Slim - internal storage enabled, 0xFE on PS TV or Slim - internal storage disabled Not present on FWs 0.931-0.990. Present on FW 3.60. Maybe not used on FWs <= 0.995 |
SceSblSsMgr#sceSblSsGetNvsDataForDriver, SceSblSsMgr#sceSblSsSetNvsDataForDriver, second_loader |
0x487 | 0x1 | Unknown | 0xFF - unknown, maybe not used on FWs <= 0.995 | second_loader |
0x4A0 | 0x1 | Update Mode | 0xFF - not update mode, other value - update step (to detail) | SceSblUpdateMgr#sceSblUsGetUpdateModeForUser, SceSblUpdateMgr#sceSblUsSetUpdateModeForUser |
0x4A1 | 0x3 | Unknown. Unused. | ||
0x4A4 | 0x4 | System Language | SceRegistryMgr, SceSblSsMgr#sceSblSsGetNvsDataForDriver, SceSblSsMgr#sceSblSsSetNvsDataForDriver | |
0x4A8 | 0x1C | Unknown. Unused. | ||
0x4C4 | 0x1 | Unknown. Set to 0 by default. | ||
0x4C5 | 0x1B | Unknown. Unused. | ||
0x4E0 | 0x20 | KibanID | Per-console ASCII string of length 22 characters. This is a serial number also present in PS3 and PS4 Serial Flash. SceSblSsMgr#sceSblSsGetNvsDataForDriver, SceSblSsMgr#sceSblSsSetNvsDataForDriver | |
0x500 | 0x1 | Wlan/Bt Flag | SceSblSsMgr#sceSblSsGetNvsDataForDriver, SceSblSsMgr#sceSblSsSetNvsDataForDriver, SceWlanBt module_start | |
0x501 | 0x1F | Unknown. Unused. | ||
0x520 | 0x80 | Activation Area | first 0x20 bytes are SceNVSKitActivationData | SceSblSsMgr, SceSblPostSsMgr |
0x5A0 | 0x100 | Qaf Token RSA signature | Not present on FW 0.990. Present on FW 3.60. Maybe added on FW 1.80. | second_loader |
0x6A0 | 0xC0 | Unknown. Unused. | ||
0x760 | 0x400 | Reserved for Test and Tool consoles. | Seems unused. |
Types
typedef struct SceNVSKitActivationData { // size is 0x20 bytes char magic[4]; // "act\n" uint32_t issue_no; uint32_t end_date; uint32_t start_date; char cmac_hash[0x10]; } SceNVSKitActivationData;
Config Storage
Config Storage is a similar storage than NVS but is accessed in a different manner. Whilst NVS is read and written by 32-byte sectors and is physically stored with a sort of history, Config Storage is written by sending scripts from Kermit to Syscon, and is not really readable but instead affects KBL Param#Hardware Info.
Sample scripts
Below are sample configstorage scripts hardcoded in SceSyscon:
const char syscon_idu_set_config[0x20] = { 0x1F, 0x54, 0x35, 0x63, 0x38, 0x62, 0x31, 0x64, 0x61, 0x63, 0x62, 0x38, 0x33, 0x36, 0x64, 0x64, 0x36, 0x63, 0x39, 0x39, 0x36, 0x38, 0x65, 0x34, 0x63, 0x30, 0x35, 0x30, 0x61, 0x36, 0x66, 0x35 }; const char syscon_idu_set_config2[0x20] = { 0x07, 0x57, 0xA8, 0x01, 0x01, 0x00, 0x0D, 0x00, 0x01, 0x4E, 0x15, 0x48, 0x51, 0xBD, 0x52, 0x2C, 0x4C, 0x83, 0x70, 0xDA, 0x4D, 0xF3, 0x8E, 0x82, 0x6B, 0xD6, 0x34, 0x98, 0x3A, 0xFD, 0xA6, 0x94 }; const char syscon_show_set_config[0x20] = { 0x1F, 0x54, 0x66, 0x63, 0x33, 0x39, 0x38, 0x39, 0x30, 0x61, 0x33, 0x32, 0x64, 0x30, 0x66, 0x32, 0x37, 0x36, 0x31, 0x35, 0x62, 0x65, 0x36, 0x65, 0x63, 0x64, 0x63, 0x35, 0x65, 0x32, 0x63, 0x63 }; const char syscon_show_set_config2[0x20] = { 0x07, 0x57, 0xA8, 0x01, 0x03, 0x00, 0x10, 0x00, 0x01, 0x4E, 0x15, 0x48, 0xB8, 0x1A, 0x54, 0xD1, 0xF2, 0xA0, 0xD1, 0x05, 0x18, 0xEA, 0x22, 0x09, 0x0A, 0x02, 0x2E, 0xAE, 0x00, 0x08, 0x25, 0xF1 }; const char syscon_clear_config[0x20] = { 0x1F, 0x54, 0x65, 0x34, 0x61, 0x65, 0x38, 0x62, 0x37, 0x61, 0x65, 0x38, 0x36, 0x33, 0x32, 0x65, 0x64, 0x64, 0x39, 0x61, 0x61, 0x65, 0x38, 0x38, 0x38, 0x39, 0x66, 0x30, 0x65, 0x65, 0x61, 0x38 }; const char syscon_clear_config2[0x20] = { 0x07, 0x57, 0xA8, 0x01, 0x00, 0x00, 0x00, 0x00, 0x01, 0x4E, 0x15, 0x48, 0x88, 0xEA, 0xC7, 0xAD, 0x65, 0xB1, 0x73, 0xC1, 0xCF, 0x48, 0xC7, 0x29, 0x1B, 0x2B, 0x8A, 0x32, 0x89, 0xCF, 0xB3, 0xC1 };
The only actual differences between those scripts are:
- the ascii string: we do not know how it is generated and what it means
- the mode value:
- A8 01 00 00 00 00 = mode clear
- A8 01 01 00 0D 00 = idu mode set
- A8 01 03 00 10 00 = show mode set
Types
// TODO
Offset | Size | Name | Sample value | Comment |
---|---|---|---|---|
0 | 1 | ascii_data_size | 0x1F | |
1 | 1 | ascii_data_flag | 0x54 | |
2 | 0x1E | ascii_data | ASCII hexadecimal string so maybe a hash | |
0x20 | 1 | unk_7_data_size | 7 | |
0x21 | 1 | unk_7_data_flag | ||
0x22 | 6 | unk_7_data | ||
0x28 | 1 | unk_1_data_size | 1 | |
0x29 | 1 | unk_1_data_flag | 0x4E | |
0x2A | 1 | sha1_hash_size | 0x15 | |
0x2B | 1 | sha1_hash_flag | 0x48 | |
0x2C | 0x14 | sha1_hash | sha1 hash of the previous blocks (data from 0 of size 0x2A) |
Config storage scripts have in theory a variable size. It is the concatenation of some blocks where the first byte is the length of the body, followed by the body of variable size. Body structure is always the same: 1 byte representing the flag, followed by data of variable size.
Usage
Theory by CelesteBlue (untested):
- 0) Begin Transaction
- 1) Load Script (part 1)
- A) configstorage data is read from SceSyscon memory
- B) configstorage data is sent by SceSyscon to Ernie
- C) Ernie FW checks hash of data and returns xx on success
if success:
- 2) Load Script (part 2)
- A) configstorage data is read from SceSyscon memory
- B) configstorage data is sent by SceSyscon to Ernie using Load
- C) Ernie FW loads data to memory and executes it
- 6) Commit Transaction
- 7) End Transaction
Pinout
A candidate package for this chip is Renesas' P121F1-50-BAL-1. It has the same size and number of pins.
UART
Name | Pin | Description |
---|---|---|
CTS0 | J7 | UART0 clear to send |
RTS0 | C6 | UART0 request to send |
TX0 | B6 | UART0 transmit |
RX0 | F11 | UART0 receive |
SW0 | A8 | Switch, see UART Console#OLED PSVita UART0 location |
SPI
Main communication with Kermit.
Name | Pin | Description |
---|---|---|
SS | A7 | Slave Select (often active low, output from master) |
MISO | A6 | Master In Slave Out (data output from slave) |
MOSI | C7 | Master Out Slave In (data output from master) |
SCLK | B7 | Serial Clock (output from master) |
Other
Name | Pin | Description |
---|---|---|
? | C11 | UDC pin 11 |
? | F9 | UDC pin 12 |
? | G4 | UDC pin 13 |
? | G8 | SN99057 pin 38 |
PWR_SW | G6 | Power switch through two transistor buffers |
Versions
Hardware Versions
There are three hardware versions of Ernie:
- NEC 78K0R/Kx3-L: present on early PS Vita prototypes (never seen)
- NEC 78K0R/Kx3: present on Fat PS Vita and PS TV models, including some prototypes such as DEM-3000L
- Renesas RL78/G13: present on Slim PS Vita models
NEC 78K0R/Kx3-L
Never seen yet but exists according to Ernie update packages.
NEC 78K0R/Kx3
NEC D79F0109 (78K0R/KH3, 121 pin)
Device Name : D79F0109
Other Device Name : SK0RT02N200GV120 (on DEM-3000L and PCH-1000)
Label:
Model <- always D79F0109 Revision <- on DEM-3000H: ES1.0, blank on others Build <- XXYYZZWWW <- XX: year, YY: week, ZZ: 2 letters (unknown usage), WWW: serial number Manufacturing country <- always "MALAYSIA"
Renesas RL78/G13
Renesas R5F1ZCRK (RL78/G13, 121 pin)
R5F1ZCRKABG#U0 R5 Renesas MCU F Flash 1 RL78 Z Customer specific C Product group R 121-pin K 384KB A Consumer grade BG VFBGA 0.4mm #U0 Tray*2
Device Name : R5F1ZCRK Device Code : 10 00 06 Firmware Version : V3.03 Code Flash 1 (Address : 0x00000000, Size : 384 K, Erase Size : 1 K) Data Flash 1 (Address : 0x000F1000, Size : 8 K, Erase Size : 1 K)
Label:
(C) XXXX <- Year Revision <- A0xxx SCEI Build <- XXYYZZWWW <- XX: year, YY: week, ZZ: 2 letters (unknown usage), WWW: serial number Unknown data
Block sizes
Ernie flash memory is erasable in blocks. Size of one block in bytes depends on the hardware version:
- NEC 78K0R/Kx3-L: 0x800
- NEC 78K0R/Kx3: 0x400
- Renesas RL78/G13: 0x400
See also [1].
Software Versions
See also [2].
Ernie firmware can be partly updated and downgraded with software updates embedded in PUP.
Ernie firmware is dependant of the hardware version and detects it based on Hardware Info.
Examples
With DevKit connected, psp2ctrl info
queries return the following results:
DEM-3000H running FW 0.990:
SysConVersion: 591105
-> converted to hexadecimal: 0x00090501 -> 0.9.5.1
PDEL-1001 running FW 1.692:
SCVersion: 0.9.2.4
PDEL-1001 running FW 3.600-3.680:
SCVersion: 1.0.3.6
Downgrade
Syscon is downgradable on DEM/PDEL/PTEL/QAF units. It might also be downgraded on retail when using a downgrade enabler like modoru.
Firmware
See Ernie Firmware