Fuses

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The Nintendo Switch uses the Tegra's fuse driver for accessing one time programmable data.

Registers

The fuse driver is mapped to physical address 0x7000F800 with a total size of 0x400 bytes and exposes several registers for fuse programming.

Erista

Registers from 0x7000F800 to 0x7000F800 + 0xFC represent the actual fuse driver which can be used to directly program the hardware fuse bitmap.

Registers from 0x7000F800 + 0x100 (FUSE_CHIP_REG_START_OFFSET) to 0x7000F800 + 0x3FC (FUSE_CHIP_REG_END_OFFSET) represent the fuse cache which holds the sensed values of certain fuses.

Driver

Name Address
FUSE_FUSECTRL 0x7000F800
FUSE_FUSEADDR 0x7000F804
FUSE_FUSERDATA 0x7000F808
FUSE_FUSEWDATA 0x7000F80C
FUSE_FUSETIME_RD1 0x7000F810
FUSE_FUSETIME_RD2 0x7000F814
FUSE_FUSETIME_PGM1 0x7000F818
FUSE_FUSETIME_PGM2 0x7000F81C
FUSE_PRIV2INTFC_START 0x7000F820
FUSE_FUSEBYPASS 0x7000F824
FUSE_PRIVATEKEYDISABLE 0x7000F828
FUSE_DISABLEREGPROGRAM 0x7000F82C
FUSE_WRITE_ACCESS_SW 0x7000F830
FUSE_PRIV2RESHIFT 0x7000F83C
FUSE_FUSETIME_RD3 0x7000F84C
FUSE_PRIVATE_KEY0_NONZERO 0x7000F880
FUSE_PRIVATE_KEY1_NONZERO 0x7000F884
FUSE_PRIVATE_KEY2_NONZERO 0x7000F888
FUSE_PRIVATE_KEY3_NONZERO 0x7000F88C
FUSE_PRIVATE_KEY4_NONZERO 0x7000F890

FUSE_FUSECTRL

Bits Description
0-1 FUSE_FUSECTRL_CMD
0x00: IDLE
0x01: READ
0x02: WRITE
0x03: SENSE_CTRL
16-20 FUSE_FUSECTRL_STATE
0x00: STATE_RESET
0x01: STATE_POST_RESET
0x02: STATE_LOAD_ROW0
0x03: STATE_LOAD_ROW1
0x04: STATE_IDLE
0x05: STATE_READ_SETUP
0x06: STATE_READ_STROBE
0x07: STATE_SAMPLE_FUSES
0x08: STATE_READ_HOLD
0x09: STATE_FUSE_SRC_SETUP
0x0A: STATE_WRITE_SETUP
0x0B: STATE_WRITE_ADDR_SETUP
0x0C: STATE_WRITE_PROGRAM
0x0D: STATE_WRITE_ADDR_HOLD
0x0E: STATE_FUSE_SRC_HOLD
0x0F: STATE_LOAD_RIR
0x10: STATE_READ_BEFORE_WRITE_SETUP
0x11: STATE_READ_DEASSERT_PD
21 FUSE_FUSECTRL_MARGIN_READ
22 FUSE_FUSECTRL_RWL
23 FUSE_FUSECTRL_TRCS
24 FUSE_FUSECTRL_AT1
25 FUSE_FUSECTRL_AT0
26 FUSE_FUSECTRL_PD_CTRL
30 FUSE_FUSECTRL_FUSE_SENSE_DONE
31 FUSE_FUSECTRL_RECORD_SHIFT_DONE

FUSE_FUSECTRL_CMD takes the fuse controller's operation mode. READ and WRITE interact directly with the hardware fuse bitmap while SENSE_CTRL flushes programmed values into the cache registers.

FUSE_FUSECTRL_STATE returns the current state of the fuse controller.

FUSE_FUSECTRL_MARGIN_READ changes the fuse read trip point setting to margin read mode.

FUSE_FUSECTRL_RWL allows accessing the RIR (redundant information row).

FUSE_FUSECTRL_TRCS allows accessing the TRCS (test rows and columns).

FUSE_FUSECTRL_AT1 selects the TRCS test column (always 0).

FUSE_FUSECTRL_AT0 selects the TRCS test row (0 or 1).

FUSE_FUSECTRL_PD_CTRL controls the fuse macro's power down mode.

FUSE_FUSECTRL_FUSE_SENSE_DONE is set if fuse sensing is completed.

FUSE_FUSECTRL_RECORD_SHIFT_DONE is set if record shifting is completed.

FUSE_FUSEADDR

Bits Description
0-7 FUSE_FUSEADDR_VLDFLD

Takes the address of the fuse to be read/written/sensed.

FUSE_FUSERDATA

Bits Description
0-31 FUSE_FUSERDATA_DATA

Returns the value read from the fuse.

FUSE_FUSEWDATA

Bits Description
0-31 FUSE_FUSEWDATA_DATA

Takes the value to be written to the fuse.

FUSE_FUSETIME_RD1

Bits Description
0-7 FUSE_FUSETIME_RD1_TSUR_MAX
8-15 FUSE_FUSETIME_RD1_TSUR_FUSEOUT
16-23 FUSE_FUSETIME_RD1_THR_MAX

FUSE_FUSETIME_RD1_TSUR_MAX takes the maximum time for STATE_READ_SETUP.

FUSE_FUSETIME_RD1_TSUR_FUSEOUT takes the time to spend on STATE_SAMPLE_FUSES.

FUSE_FUSETIME_RD1_THR_MAX takes the maximum time for STATE_READ_HOLD.

FUSE_FUSETIME_RD2

Bits Description
0-15 FUSE_FUSETIME_RD2_TWIDTH_RD

Takes the read strobe pulse width used during STATE_READ_STROBE.

FUSE_FUSETIME_PGM1

Bits Description
0-7 FUSE_FUSETIME_PGM1_TSUP_MAX
8-15 FUSE_FUSETIME_PGM1_TSUP_ADDR
16-23 FUSE_FUSETIME_PGM1_THP_ADDR
24-31 FUSE_FUSETIME_PGM1_THP_PS

FUSE_FUSETIME_PGM1_TSUP_MAX takes the maximum time for STATE_WRITE_SETUP.

FUSE_FUSETIME_PGM1_TSUP_ADDR takes the time to spend on STATE_WRITE_ADDR_SETUP.

FUSE_FUSETIME_PGM1_THP_ADDR takes the time to spend on STATE_WRITE_ADDR_HOLD.

FUSE_FUSETIME_PGM1_THP_PS takes the time to spend on STATE_FUSE_SRC_HOLD.

FUSE_FUSETIME_PGM2

Bits Description
0-15 FUSE_FUSETIME_PGM2_TWIDTH_PGM
16-23 FUSE_FUSETIME_PGM2_TSUP_PS
24-31 FUSE_FUSETIME_PGM2_THP_CSPS

FUSE_FUSETIME_PGM2_TWIDTH_PGM takes the program strobe pulse width used during STATE_WRITE_PROGRAM.

FUSE_FUSETIME_PGM2_TSUP_PS takes the time to spend on STATE_FUSE_SRC_SETUP.

FUSE_FUSETIME_PGM2_THP_CSPS takes the time to spend on STATE_READ_BEFORE_WRITE_SETUP.

FUSE_PRIV2INTFC_START

Bits Description
0 FUSE_PRIV2INTFC_START_DATA
1 FUSE_PRIV2INTFC_SKIP_RECORDS

Controls the interface between the internal fuse chip (INTFC) and the fuse cache registers (PRIV).

FUSE_FUSEBYPASS

Bits Description
0 FUSE_FUSEBYPASS_VAL

If set, this register enables fuse bypass mode. This is only available in hardware where the production_mode fuse remains unburnt.

FUSE_PRIVATEKEYDISABLE

Bits Description
0 FUSE_PRIVATEKEYDISABLE_VAL
4 FUSE_PRIVATEKEYDISABLE_TZ_STICKY_BIT_VAL

If set, this register hides the private_key fuses until the next reset.

FUSE_DISABLEREGPROGRAM

Bits Description
0 FUSE_DISABLEREGPROGRAM_VAL

If set, this register disables fuse programming until the next reset.

FUSE_WRITE_ACCESS_SW

Bits Description
0 FUSE_WRITE_ACCESS_SW_CTRL
16 FUSE_WRITE_ACCESS_SW_STATUS

Controls and returns the status of software writes to the fuse cache registers.

FUSE_PRIV2RESHIFT

Bits Description
0 FUSE_PRIV2RESHIFT_TRIGENABLE_VAL
1 FUSE_PRIV2RESHIFT_TRIG_1_FCPU0_VAL
2 FUSE_PRIV2RESHIFT_TRIG_1_FCPU1_VAL
3 FUSE_PRIV2RESHIFT_TRIG_1_FCPU2_VAL
4 FUSE_PRIV2RESHIFT_TRIG_1_FCPU3_VAL
5 FUSE_PRIV2RESHIFT_TRIG_1_FL2_TBANK0_VAL
6 FUSE_PRIV2RESHIFT_TRIG_1_FL2_TBANK1_VAL
7 FUSE_PRIV2RESHIFT_TRIG_1_FL2_TBANK2_VAL
8 FUSE_PRIV2RESHIFT_TRIG_1_FL2_TBANK3_VAL
9 FUSE_PRIV2RESHIFT_TRIG_1_SCPU_VAL
10 FUSE_PRIV2RESHIFT_TRIG_1_SL2_TBANK_VAL
11 FUSE_PRIV2RESHIFT_STATUS_1_FCPU0_VAL
12 FUSE_PRIV2RESHIFT_STATUS_1_FCPU1_VAL
13 FUSE_PRIV2RESHIFT_STATUS_1_FCPU2_VAL
14 FUSE_PRIV2RESHIFT_STATUS_1_FCPU3_VAL
15 FUSE_PRIV2RESHIFT_STATUS_1_FL2_TBANK0_VAL
16 FUSE_PRIV2RESHIFT_STATUS_1_FL2_TBANK1_VAL
17 FUSE_PRIV2RESHIFT_STATUS_1_FL2_TBANK2_VAL
18 FUSE_PRIV2RESHIFT_STATUS_1_FL2_TBANK3_VAL
19 FUSE_PRIV2RESHIFT_STATUS_1_SCPU_VAL
20 FUSE_PRIV2RESHIFT_STATUS_1_SL2_TBANK_VAL

Controls and returns the status of the record shift (RESHIFT) hardware block used for RAM re-repair.

FUSE_FUSETIME_RD3

Bits Description
0-15 FUSE_FUSETIME_RD3_TSUR_PDCS

Takes the time to spend on STATE_READ_DEASSERT_PD.

FUSE_PRIVATE_KEY0_NONZERO

Bits Description
0 FUSE_PRIVATE_KEY0_NONZERO_DATA

Returns whether private_key0 is empty or not.

FUSE_PRIVATE_KEY1_NONZERO

Bits Description
0 FUSE_PRIVATE_KEY1_NONZERO_DATA

Returns whether private_key1 is empty or not.

FUSE_PRIVATE_KEY2_NONZERO

Bits Description
0 FUSE_PRIVATE_KEY2_NONZERO_DATA

Returns whether private_key2 is empty or not.

FUSE_PRIVATE_KEY3_NONZERO

Bits Description
0 FUSE_PRIVATE_KEY3_NONZERO_DATA

Returns whether private_key3 is empty or not.

FUSE_PRIVATE_KEY4_NONZERO

Bits Description
0 FUSE_PRIVATE_KEY4_NONZERO_DATA

Returns whether private_key4 is empty or not.

Cache

Name Address
FUSE_PRODUCTION_MODE 0x7000F900
FUSE_JTAG_SECUREID_VALID 0x7000F904
FUSE_ODM_LOCK 0x7000F908
FUSE_OPT_OPENGL_EN 0x7000F90C
FUSE_SKU_INFO 0x7000F910
FUSE_CPU_SPEEDO_0_CALIB 0x7000F914
FUSE_CPU_IDDQ_CALIB 0x7000F918
FUSE_OPT_FT_REV 0x7000F928
FUSE_CPU_SPEEDO_1_CALIB 0x7000F92C
FUSE_CPU_SPEEDO_2_CALIB 0x7000F930
FUSE_SOC_SPEEDO_0_CALIB 0x7000F934
FUSE_SOC_SPEEDO_1_CALIB 0x7000F938
FUSE_SOC_SPEEDO_2_CALIB 0x7000F93C
FUSE_SOC_IDDQ_CALIB 0x7000F940
FUSE_FA 0x7000F948
FUSE_RESERVED_PRODUCTION 0x7000F94C
FUSE_HDMI_LANE0_CALIB 0x7000F950
FUSE_HDMI_LANE1_CALIB 0x7000F954
FUSE_HDMI_LANE2_CALIB 0x7000F958
FUSE_HDMI_LANE3_CALIB 0x7000F95C
FUSE_ENCRYPTION_RATE 0x7000F960
FUSE_PUBLIC_KEY0 0x7000F964
FUSE_PUBLIC_KEY1 0x7000F968
FUSE_PUBLIC_KEY2 0x7000F96C
FUSE_PUBLIC_KEY3 0x7000F970
FUSE_PUBLIC_KEY4 0x7000F974
FUSE_PUBLIC_KEY5 0x7000F978
FUSE_PUBLIC_KEY6 0x7000F97C
FUSE_PUBLIC_KEY7 0x7000F980
FUSE_TSENSOR1_CALIB 0x7000F984
FUSE_TSENSOR2_CALIB 0x7000F988
FUSE_OPT_CP_REV 0x7000F990
FUSE_OPT_PFG 0x7000F994
FUSE_TSENSOR0_CALIB 0x7000F998
FUSE_FIRST_BOOTROM_PATCH_SIZE 0x7000F99C
FUSE_SECURITY_MODE 0x7000F9A0
FUSE_PRIVATE_KEY0 0x7000F9A4
FUSE_PRIVATE_KEY1 0x7000F9A8
FUSE_PRIVATE_KEY2 0x7000F9AC
FUSE_PRIVATE_KEY3 0x7000F9B0
FUSE_PRIVATE_KEY4 0x7000F9B4
FUSE_ARM_JTAG_DIS 0x7000F9B8
FUSE_BOOT_DEVICE_INFO 0x7000F9BC
FUSE_RESERVED_SW 0x7000F9C0
FUSE_OPT_VP9_DISABLE 0x7000F9C4
FUSE_RESERVED_ODM0 0x7000F9C8
FUSE_RESERVED_ODM1 0x7000F9CC
FUSE_RESERVED_ODM2 0x7000F9D0
FUSE_RESERVED_ODM3 0x7000F9D4
FUSE_RESERVED_ODM4 0x7000F9D8
FUSE_RESERVED_ODM5 0x7000F9DC
FUSE_RESERVED_ODM6 0x7000F9E0
FUSE_RESERVED_ODM7 0x7000F9E4
FUSE_OBS_DIS 0x7000F9E8
FUSE_USB_CALIB 0x7000F9F0
FUSE_SKU_DIRECT_CONFIG 0x7000F9F4
FUSE_KFUSE_PRIVKEY_CTRL 0x7000F9F8
FUSE_PACKAGE_INFO 0x7000F9FC
FUSE_OPT_VENDOR_CODE 0x7000FA00
FUSE_OPT_FAB_CODE 0x7000FA04
FUSE_OPT_LOT_CODE_0 0x7000FA08
FUSE_OPT_LOT_CODE_1 0x7000FA0C
FUSE_OPT_WAFER_ID 0x7000FA10
FUSE_OPT_X_COORDINATE 0x7000FA14
FUSE_OPT_Y_COORDINATE 0x7000FA18
FUSE_OPT_SEC_DEBUG_EN 0x7000FA1C
FUSE_OPT_OPS_RESERVED 0x7000FA20
FUSE_SATA_CALIB 0x7000FA24
FUSE_GPU_IDDQ_CALIB 0x7000FA28
FUSE_TSENSOR3_CALIB 0x7000FA2C
FUSE_CLOCK_BOUNDOUT0 0x7000FA30
FUSE_CLOCK_BOUNDOUT1 0x7000FA34
FUSE_OPT_SAMPLE_TYPE 0x7000FA44
FUSE_OPT_SUBREVISION 0x7000FA48
FUSE_OPT_SW_RESERVED_0 0x7000FA4C
FUSE_OPT_SW_RESERVED_1 0x7000FA50
FUSE_TSENSOR4_CALIB 0x7000FA54
FUSE_TSENSOR5_CALIB 0x7000FA58
FUSE_TSENSOR6_CALIB 0x7000FA5C
FUSE_TSENSOR7_CALIB 0x7000FA60
FUSE_OPT_PRIV_SEC_DIS 0x7000FA64
FUSE_PKC_DISABLE 0x7000FA68
FUSE_FUSE2TSEC_DEBUG_DISABLE 0x7000FA7C
FUSE_TSENSOR_COMMON 0x7000FA80
FUSE_OPT_CP_BIN 0x7000FA84
FUSE_OPT_GPU_DISABLE 0x7000FA88
FUSE_OPT_FT_BIN 0x7000FA8C
FUSE_OPT_DONE_MAP 0x7000FA90
FUSE_APB2JTAG_DISABLE 0x7000FA98
FUSE_ODM_INFO 0x7000FA9C
FUSE_ARM_CRYPT_DE_FEATURE 0x7000FAA8
FUSE_WOA_SKU_FLAG 0x7000FAC0
FUSE_ECO_RESERVE_1 0x7000FAC4
FUSE_GCPLEX_CONFIG_FUSE 0x7000FAC8
FUSE_PRODUCTION_MONTH 0x7000FACC
FUSE_RAM_REPAIR_INDICATOR 0x7000FAD0
FUSE_TSENSOR9_CALIB 0x7000FAD4
FUSE_VMIN_CALIBRATION 0x7000FADC
FUSE_AGING_SENSOR_CALIBRATION 0x7000FAE0
FUSE_DEBUG_AUTHENTICATION 0x7000FAE4
FUSE_SECURE_PROVISION_INDEX 0x7000FAE8
FUSE_SECURE_PROVISION_INFO 0x7000FAEC
FUSE_OPT_GPU_DISABLE_CP1 0x7000FAF0
FUSE_SPARE_ENDIS 0x7000FAF4
FUSE_ECO_RESERVE_0 0x7000FAF8
FUSE_RESERVED_CALIB0 0x7000FB04
FUSE_RESERVED_CALIB1 0x7000FB08
FUSE_OPT_GPU_TPC0_DISABLE 0x7000FB0C
FUSE_OPT_GPU_TPC0_DISABLE_CP1 0x7000FB10
FUSE_OPT_CPU_DISABLE 0x7000FB14
FUSE_OPT_CPU_DISABLE_CP1 0x7000FB18
FUSE_TSENSOR10_CALIB 0x7000FB1C
FUSE_TSENSOR10_CALIB_AUX 0x7000FB20
FUSE_OPT_RAM_SVOP_DP 0x7000FB24
FUSE_OPT_RAM_SVOP_PDP 0x7000FB28
FUSE_OPT_RAM_SVOP_REG 0x7000FB2C
FUSE_OPT_RAM_SVOP_SP 0x7000FB30
FUSE_OPT_RAM_SVOP_SMPDP 0x7000FB34
FUSE_OPT_GPU_TPC0_DISABLE_CP2 0x7000FB38
FUSE_OPT_GPU_TPC1_DISABLE 0x7000FB3C
FUSE_OPT_GPU_TPC1_DISABLE_CP1 0x7000FB40
FUSE_OPT_GPU_TPC1_DISABLE_CP2 0x7000FB44
FUSE_OPT_CPU_DISABLE_CP2 0x7000FB48
FUSE_OPT_GPU_DISABLE_CP2 0x7000FB4C
FUSE_USB_CALIB_EXT 0x7000FB50
FUSE_RESERVED_FIELD 0x7000FB54
FUSE_SPARE_REALIGNMENT_REG 0x7000FB7C
FUSE_SPARE_BIT_0 0x7000FB80
FUSE_SPARE_BIT_1 0x7000FB84
FUSE_SPARE_BIT_2 0x7000FB88
FUSE_SPARE_BIT_3 0x7000FB8C
FUSE_SPARE_BIT_4 0x7000FB90
FUSE_SPARE_BIT_5 0x7000FB94
FUSE_SPARE_BIT_6 0x7000FB98
FUSE_SPARE_BIT_7 0x7000FB9C
FUSE_SPARE_BIT_8 0x7000FBA0
FUSE_SPARE_BIT_9 0x7000FBA4
FUSE_SPARE_BIT_10 0x7000FBA8
FUSE_SPARE_BIT_11 0x7000FBAC
FUSE_SPARE_BIT_12 0x7000FBB0
FUSE_SPARE_BIT_13 0x7000FBB4
FUSE_SPARE_BIT_14 0x7000FBB8
FUSE_SPARE_BIT_15 0x7000FBBC
FUSE_SPARE_BIT_16 0x7000FBC0
FUSE_SPARE_BIT_17 0x7000FBC4
FUSE_SPARE_BIT_18 0x7000FBC8
FUSE_SPARE_BIT_19 0x7000FBCC
FUSE_SPARE_BIT_20 0x7000FBD0
FUSE_SPARE_BIT_21 0x7000FBD4
FUSE_SPARE_BIT_22 0x7000FBD8
FUSE_SPARE_BIT_23 0x7000FBDC
FUSE_SPARE_BIT_24 0x7000FBE0
FUSE_SPARE_BIT_25 0x7000FBE4
FUSE_SPARE_BIT_26 0x7000FBE8
FUSE_SPARE_BIT_27 0x7000FBEC
FUSE_SPARE_BIT_28 0x7000FBF0
FUSE_SPARE_BIT_29 0x7000FBF4
FUSE_SPARE_BIT_30 0x7000FBF8
FUSE_SPARE_BIT_31 0x7000FBFC

FUSE_SKU_INFO

Stores the SKU ID (must be 0x83).

FUSE_OPT_FT_REV

Stores the FT (Final Test) revision.

Original Erista units have this value set to 0xA0 (revision 5.0). The first batch of patched Erista units have this value set to 0xC0 (revision 6.0). The second batch of patched Erista units have this value set to 0xE0 (revision 7.0).

Mariko and Lite units have this value set to 0x60 (revision 3.0). OLED units have this value set to 0x81 (revision 4.1).

FUSE_SOC_SPEEDO_1_CALIB

Stores the bootrom patch version.

FUSE_FA

Stores failure analysis mode.

FUSE_PUBLIC_KEY

Stores the SHA256 hash of the 2048-bit RSA key expected at BCT+0x210.

FUSE_OPT_CP_REV

Stores the CP (Chip Probing) revision.

Original Erista units have this value set to 0xA0 (revision 5.0). Patched Erista units have this value set to 0x103 (revision 8.3).

Mariko units have this value set to 0x40 (revision 2.0). Lite units have this value set to 0x41 (revision 2.1). OLED units have this value set to 0x100 (revision 8.0).

FUSE_PRIVATE_KEY

Stores the 160-bit private key (128 bit SBK + 32-bit device key).

Reads to these registers after FUSE_PRIVATEKEYDISABLE is set produce all-FF output.

FUSE_ARM_JTAG_DIS

Controls access to the Arm JTAG interface.

Production Erista and Mariko units have this value set to 0x1, while development Erista and Mariko units do not.

FUSE_RESERVED_SW

Bits Description
0-2 Boot device
3 Skip device selection straps
4 Enable charger detection
5 Enable watchdog
6 Forced RCM two button mode (0 = VOLUME_UP, 1 = VOLUME_UP + HOME)
7 RCM USB controller mode (0 = USB 2.0, 1 = XUSB)

Stores software reserved configuration values.

Production Erista and Mariko units have the forced RCM two button mode set, while development Erista and Mariko units do not.

Original Erista units have the RCM USB controller mode set to USB 2.0, while the first batch of patched Erista units have the RCM USB controller mode set to XUSB. Mariko ignores this and uses XUSB regardless for RCM.

FUSE_RESERVED_ODM0

Bits Description
0-31 OdmTestId0

FUSE_RESERVED_ODM1

Bits Description
0-31 OdmTestId1

FUSE_RESERVED_ODM2

Bits Description
0-31 OdmTestId2

[5.0.0+] If FormatVersion is 1, this becomes:

Bits Description
0-4 DeviceUniqueKeyGeneration
5-31 Reserved

FUSE_RESERVED_ODM3

Bits Description
0-31 OdmTestId3

[5.0.0+] If FormatVersion is 1, this becomes:

Bits Description
0-31 Reserved

FUSE_RESERVED_ODM4

Bits Description
0-1 HardwareState1
2 HardwareType1
[1.0.0-3.0.2] 3-5

[4.0.0+] 3-7

[15.0.0+] DramId1 ([4.0.0-14.1.2] DramId)
8 HardwareType2
9 HardwareState2
10 [3.0.0+] QuestState
11 [5.0.0+] FormatVersion
12-14 [15.0.0+] DramId2
16-19 [4.0.0+] HardwareType3

Stores device configuration parameters.

FUSE_RESERVED_ODM5

Empty and unused.

FUSE_RESERVED_ODM6

Returns the value of the reserved_odm6 anti-downgrade fuse.

FUSE_RESERVED_ODM7

Returns the value of the reserved_odm7 anti-downgrade fuse.

FUSE_SKU_DIRECT_CONFIG

Bits Description
0 Disable SCPU
1 Disable FCPU0
2 Disable FCPU1
3 Disable FCPU2
4 Disable FCPU3
5 Disable all CPUs

Controls which CPUs can be used.

Erista units have this value set to 0x00 (both Cortex-A53 and Cortex-A57 clusters are usable).

Mariko units have this value set to 0x01 (only the Cortex-A57 cluster is usable).

FUSE_OPT_SEC_DEBUG_EN

Controls the Falcon SCP debug mode.

FUSE_OPT_PRIV_SEC_DIS

Controls the Falcon Light Secure feature.

FUSE_PKC_DISABLE

Returns if public key crypto is used or not.

FUSE_ODM_INFO

Bits Description
0-7 Reserved
8 Disable DBGEN
9 Disable NIDEN
10 Disable SPIDEN
11 Disable SPNIDEN
12 Disable DEVICEEN

Production Erista and Mariko units have this value set to 0x1F00 (all signals disabled).

Development Erista and Mariko units have this value set to 0x0000 (all signals enabled).

FUSE_ECO_RESERVE_0

Returns the chip unique AID.

FUSE_SPARE_BIT_2

Bits Description
0 Speedo fusing revision

FUSE_SPARE_BIT_3

Bits Description
0 Speedo fusing revision

FUSE_SPARE_BIT_4

Bits Description
0 Speedo fusing revision

FUSE_SPARE_BIT_5

Must be non-zero on production units, otherwise the first bootloader panics. On prototype units it can be zero, which tells the bootloader to choose from two pre-production master key seeds. If set to non-zero on a prototype unit, it tells the bootloader to choose from two master key seeds (with the second one being the same as the production master key seed).

[4.0.0+] This value is no longer used during boot.

Mariko

Registers from 0x7000F800 to 0x7000F800 + 0x94 represent the actual fuse driver which can be used to directly program the hardware fuse bitmap.

Registers from 0x7000F800 + 0x98 to 0x7000F800 + 0x3FC represent the fuse cache which holds the sensed values of certain fuses.

Driver

Name Address
FUSE_FUSECTRL 0x7000F800
FUSE_FUSEADDR 0x7000F804
FUSE_FUSERDATA 0x7000F808
FUSE_FUSEWDATA 0x7000F80C
FUSE_FUSETIME_RD1 0x7000F810
FUSE_FUSETIME_RD2 0x7000F814
FUSE_FUSETIME_PGM1 0x7000F818
FUSE_FUSETIME_PGM2 0x7000F81C
FUSE_PRIV2INTFC_START 0x7000F820
FUSE_FUSEBYPASS 0x7000F824
FUSE_PRIVATEKEYDISABLE 0x7000F828
FUSE_DISABLEREGPROGRAM 0x7000F82C
FUSE_WRITE_ACCESS_SW 0x7000F830
FUSE_PRIV2RESHIFT 0x7000F83C
FUSE_FUSETIME_RD3 0x7000F84C
FUSE_SPARE_ADDR_START 0x7000F860
FUSE_PRIVATE_KEY0_NONZERO 0x7000F880
FUSE_PRIVATE_KEY1_NONZERO 0x7000F884
FUSE_PRIVATE_KEY2_NONZERO 0x7000F888
FUSE_PRIVATE_KEY3_NONZERO 0x7000F88C
FUSE_PRIVATE_KEY4_NONZERO 0x7000F890

FUSE_SPARE_ADDR_START

Bits Description
0-31 FUSE_SPARE_ADDR_START_DATA

Returns the offset of the spare bit fuse registers (always 0x380).

Cache

Name Address
FUSE_RESERVED_ODM8 0x7000F898
FUSE_RESERVED_ODM9 0x7000F89C
FUSE_RESERVED_ODM10 0x7000F8A0
FUSE_RESERVED_ODM11 0x7000F8A4
FUSE_RESERVED_ODM12 0x7000F8A8
FUSE_RESERVED_ODM13 0x7000F8AC
FUSE_RESERVED_ODM14 0x7000F8B0
FUSE_RESERVED_ODM15 0x7000F8B4
FUSE_RESERVED_ODM16 0x7000F8B8
FUSE_RESERVED_ODM17 0x7000F8BC
FUSE_RESERVED_ODM18 0x7000F8C0
FUSE_RESERVED_ODM19 0x7000F8C4
FUSE_RESERVED_ODM20 0x7000F8C8
FUSE_RESERVED_ODM21 0x7000F8CC
FUSE_KEK00 0x7000F8D0
FUSE_KEK01 0x7000F8D4
FUSE_KEK02 0x7000F8D8
FUSE_KEK03 0x7000F8DC
FUSE_BEK00 0x7000F8E0
FUSE_BEK01 0x7000F8E4
FUSE_BEK02 0x7000F8E8
FUSE_BEK03 0x7000F8EC
FUSE_OPT_RAM_RTSEL_TSMCSP_PO4SVT 0x7000F8F0
FUSE_OPT_RAM_WTSEL_TSMCSP_PO4SVT 0x7000F8F4
FUSE_OPT_RAM_RTSEL_TSMCPDP_PO4SVT 0x7000F8F8
FUSE_OPT_RAM_MTSEL_TSMCPDP_PO4SVT 0x7000F8FC
FUSE_PRODUCTION_MODE 0x7000F900
FUSE_JTAG_SECUREID_VALID 0x7000F904
FUSE_ODM_LOCK 0x7000F908
FUSE_OPT_OPENGL_EN 0x7000F90C
FUSE_SKU_INFO 0x7000F910
FUSE_CPU_SPEEDO_0_CALIB 0x7000F914
FUSE_CPU_IDDQ_CALIB 0x7000F918
FUSE_RESERVED_ODM22 0x7000F91C
FUSE_RESERVED_ODM23 0x7000F920
FUSE_RESERVED_ODM24 0x7000F924
FUSE_OPT_FT_REV 0x7000F928
FUSE_CPU_SPEEDO_1_CALIB 0x7000F92C
FUSE_CPU_SPEEDO_2_CALIB 0x7000F930
FUSE_SOC_SPEEDO_0_CALIB 0x7000F934
FUSE_SOC_SPEEDO_1_CALIB 0x7000F938
FUSE_SOC_SPEEDO_2_CALIB 0x7000F93C
FUSE_SOC_IDDQ_CALIB 0x7000F940
FUSE_RESERVED_ODM25 0x7000F944
FUSE_FA 0x7000F948
FUSE_RESERVED_PRODUCTION 0x7000F94C
FUSE_HDMI_LANE0_CALIB 0x7000F950
FUSE_HDMI_LANE1_CALIB 0x7000F954
FUSE_HDMI_LANE2_CALIB 0x7000F958
FUSE_HDMI_LANE3_CALIB 0x7000F95C
FUSE_ENCRYPTION_RATE 0x7000F960
FUSE_PUBLIC_KEY0 0x7000F964
FUSE_PUBLIC_KEY1 0x7000F968
FUSE_PUBLIC_KEY2 0x7000F96C
FUSE_PUBLIC_KEY3 0x7000F970
FUSE_PUBLIC_KEY4 0x7000F974
FUSE_PUBLIC_KEY5 0x7000F978
FUSE_PUBLIC_KEY6 0x7000F97C
FUSE_PUBLIC_KEY7 0x7000F980
FUSE_TSENSOR1_CALIB 0x7000F984
FUSE_TSENSOR2_CALIB 0x7000F988
FUSE_OPT_SECURE_SCC_DIS 0x7000F98C
FUSE_OPT_CP_REV 0x7000F990
FUSE_OPT_PFG 0x7000F994
FUSE_TSENSOR0_CALIB 0x7000F998
FUSE_FIRST_BOOTROM_PATCH_SIZE 0x7000F99C
FUSE_SECURITY_MODE 0x7000F9A0
FUSE_PRIVATE_KEY0 0x7000F9A4
FUSE_PRIVATE_KEY1 0x7000F9A8
FUSE_PRIVATE_KEY2 0x7000F9AC
FUSE_PRIVATE_KEY3 0x7000F9B0
FUSE_PRIVATE_KEY4 0x7000F9B4
FUSE_ARM_JTAG_DIS 0x7000F9B8
FUSE_BOOT_DEVICE_INFO 0x7000F9BC
FUSE_RESERVED_SW 0x7000F9C0
FUSE_OPT_VP9_DISABLE 0x7000F9C4
FUSE_RESERVED_ODM0 0x7000F9C8
FUSE_RESERVED_ODM1 0x7000F9CC
FUSE_RESERVED_ODM2 0x7000F9D0
FUSE_RESERVED_ODM3 0x7000F9D4
FUSE_RESERVED_ODM4 0x7000F9D8
FUSE_RESERVED_ODM5 0x7000F9DC
FUSE_RESERVED_ODM6 0x7000F9E0
FUSE_RESERVED_ODM7 0x7000F9E4
FUSE_OBS_DIS 0x7000F9E8
FUSE_OPT_NVJTAG_PROTECTION_ENABLE 0x7000F9EC
FUSE_USB_CALIB 0x7000F9F0
FUSE_SKU_DIRECT_CONFIG 0x7000F9F4
FUSE_KFUSE_PRIVKEY_CTRL 0x7000F9F8
FUSE_PACKAGE_INFO 0x7000F9FC
FUSE_OPT_VENDOR_CODE 0x7000FA00
FUSE_OPT_FAB_CODE 0x7000FA04
FUSE_OPT_LOT_CODE_0 0x7000FA08
FUSE_OPT_LOT_CODE_1 0x7000FA0C
FUSE_OPT_WAFER_ID 0x7000FA10
FUSE_OPT_X_COORDINATE 0x7000FA14
FUSE_OPT_Y_COORDINATE 0x7000FA18
FUSE_OPT_SEC_DEBUG_EN 0x7000FA1C
FUSE_OPT_OPS_RESERVED 0x7000FA20
0x7000FA24
FUSE_GPU_IDDQ_CALIB 0x7000FA28
FUSE_TSENSOR3_CALIB 0x7000FA2C
FUSE_CLOCK_BONDOUT0 0x7000FA30
FUSE_CLOCK_BONDOUT1 0x7000FA34
FUSE_RESERVED_ODM26 0x7000FA38
FUSE_RESERVED_ODM27 0x7000FA3C
FUSE_RESERVED_ODM28 0x7000FA40
FUSE_OPT_SAMPLE_TYPE 0x7000FA44
FUSE_OPT_SUBREVISION 0x7000FA48
FUSE_OPT_SW_RESERVED_0 0x7000FA4C
FUSE_OPT_SW_RESERVED_1 0x7000FA50
FUSE_TSENSOR4_CALIB 0x7000FA54
FUSE_TSENSOR5_CALIB 0x7000FA58
FUSE_TSENSOR6_CALIB 0x7000FA5C
FUSE_TSENSOR7_CALIB 0x7000FA60
FUSE_OPT_PRIV_SEC_DIS 0x7000FA64
FUSE_BOOT_SECURITY_INFO 0x7000FA68
FUSE_OPT_RAM_RTSEL_TSMCSP_PO4HVT 0x7000FA6C
FUSE_OPT_RAM_WTSEL_TSMCSP_PO4HVT 0x7000FA70
FUSE_OPT_RAM_RTSEL_TSMCPDP_PO4HVT 0x7000FA74
FUSE_OPT_RAM_MTSEL_TSMCPDP_PO4HVT 0x7000FA78
FUSE_FUSE2TSEC_DEBUG_DISABLE 0x7000FA7C
FUSE_TSENSOR_COMMON 0x7000FA80
FUSE_OPT_CP_BIN 0x7000FA84
FUSE_OPT_GPU_DISABLE 0x7000FA88
FUSE_OPT_FT_BIN 0x7000FA8C
FUSE_OPT_DONE_MAP 0x7000FA90
FUSE_RESERVED_ODM29 0x7000FA94
FUSE_APB2JTAG_DISABLE 0x7000FA98
FUSE_ODM_INFO 0x7000FA9C
FUSE_ARM_CRYPT_DE_FEATURE 0x7000FAA8
FUSE_OPT_RAM_WTSEL_TSMCPDP_PO4SVT 0x7000FAB0
FUSE_OPT_RAM_RCT_TSMCDP_PO4SVT 0x7000FAB4
FUSE_OPT_RAM_WCT_TSMCDP_PO4SVT 0x7000FAB8
FUSE_OPT_RAM_KP_TSMCDP_PO4SVT 0x7000FABC
FUSE_WOA_SKU_FLAG 0x7000FAC0
FUSE_ECO_RESERVE_1 0x7000FAC4
FUSE_GCPLEX_CONFIG_FUSE 0x7000FAC8
FUSE_PRODUCTION_MONTH 0x7000FACC
FUSE_RAM_REPAIR_INDICATOR 0x7000FAD0
FUSE_TSENSOR9_CALIB 0x7000FAD4
FUSE_VMIN_CALIBRATION 0x7000FADC
FUSE_AGING_SENSOR_CALIBRATION 0x7000FAE0
FUSE_DEBUG_AUTHENTICATION 0x7000FAE4
FUSE_SECURE_PROVISION_INDEX 0x7000FAE8
FUSE_SECURE_PROVISION_INFO 0x7000FAEC
FUSE_OPT_GPU_DISABLE_CP1 0x7000FAF0
FUSE_SPARE_ENDIS 0x7000FAF4
FUSE_ECO_RESERVE_0 0x7000FAF8
FUSE_RESERVED_CALIB0 0x7000FB04
FUSE_RESERVED_CALIB1 0x7000FB08
FUSE_OPT_GPU_TPC0_DISABLE 0x7000FB0C
FUSE_OPT_GPU_TPC0_DISABLE_CP1 0x7000FB10
FUSE_OPT_CPU_DISABLE 0x7000FB14
FUSE_OPT_CPU_DISABLE_CP1 0x7000FB18
FUSE_TSENSOR10_CALIB 0x7000FB1C
FUSE_TSENSOR10_CALIB_AUX 0x7000FB20
FUSE_OPT_RAM_WTSEL_TSMCPDP_PO4HVT 0x7000FB24
FUSE_OPT_RAM_RCT_TSMCDP_PO4HVT 0x7000FB28
FUSE_OPT_RAM_WCT_TSMCDP_PO4HVT 0x7000FB2C
FUSE_OPT_RAM_KP_TSMCDP_PO4HVT 0x7000FB30
0x7000FB34
FUSE_OPT_GPU_TPC0_DISABLE_CP2 0x7000FB38
FUSE_OPT_GPU_TPC1_DISABLE 0x7000FB3C
FUSE_OPT_GPU_TPC1_DISABLE_CP1 0x7000FB40
FUSE_OPT_GPU_TPC1_DISABLE_CP2 0x7000FB44
FUSE_OPT_CPU_DISABLE_CP2 0x7000FB48
FUSE_OPT_GPU_DISABLE_CP2 0x7000FB4C
FUSE_USB_CALIB_EXT 0x7000FB50
FUSE_RESERVED_FIELD 0x7000FB54
FUSE_SPARE_REALIGNMENT_REG 0x7000FB7C
FUSE_SPARE_BIT_0 0x7000FB80
FUSE_SPARE_BIT_1 0x7000FB84
FUSE_SPARE_BIT_2 0x7000FB88
FUSE_SPARE_BIT_3 0x7000FB8C
FUSE_SPARE_BIT_4 0x7000FB90
FUSE_SPARE_BIT_5 0x7000FB94
FUSE_SPARE_BIT_6 0x7000FB98
FUSE_SPARE_BIT_7 0x7000FB9C
FUSE_SPARE_BIT_8 0x7000FBA0
FUSE_SPARE_BIT_9 0x7000FBA4
FUSE_SPARE_BIT_10 0x7000FBA8
FUSE_SPARE_BIT_11 0x7000FBAC
FUSE_SPARE_BIT_12 0x7000FBB0
FUSE_SPARE_BIT_13 0x7000FBB4
FUSE_SPARE_BIT_14 0x7000FBB8
FUSE_SPARE_BIT_15 0x7000FBBC
FUSE_SPARE_BIT_16 0x7000FBC0
FUSE_SPARE_BIT_17 0x7000FBC4
FUSE_SPARE_BIT_18 0x7000FBC8
FUSE_SPARE_BIT_19 0x7000FBCC
FUSE_SPARE_BIT_20 0x7000FBD0
FUSE_SPARE_BIT_21 0x7000FBD4
FUSE_SPARE_BIT_22 0x7000FBD8
FUSE_SPARE_BIT_23 0x7000FBDC
FUSE_SPARE_BIT_24 0x7000FBE0
FUSE_SPARE_BIT_25 0x7000FBE4
FUSE_SPARE_BIT_26 0x7000FBE8
FUSE_SPARE_BIT_27 0x7000FBEC
FUSE_SPARE_BIT_28 0x7000FBF0
FUSE_SPARE_BIT_29 0x7000FBF4

FUSE_KEK

Stores the 128-bit KEK (Key Encryption Key) encrypted with the FEK (Fuse Encryption Key) selected by FUSE_RESERVED_PRODUCTION and FUSE_BOOT_SECURITY_INFO.

Reads to these registers after FUSE_PRIVATEKEYDISABLE is set produce all-FF output.

FUSE_BEK

Stores the 128-bit BEK (Boot Encryption Key) encrypted with the FEK (Fuse Encryption Key) selected by FUSE_RESERVED_PRODUCTION and FUSE_BOOT_SECURITY_INFO.

Reads to these registers after FUSE_PRIVATEKEYDISABLE is set produce all-FF output.

FUSE_RESERVED_PRODUCTION

Bits Description
0-1 Reserved
2 FEK bank select

FUSE_OPT_NVJTAG_PROTECTION_ENABLE

Controls the NVJTAG protection feature. If enabled, this will permanently disable access to all DFT (Design for Test) functions which include the ability put the chip in FA (Failure Analysis) mode.

FUSE_RESERVED_ODM28

Bits Description
0 RegulatorType

FUSE_BOOT_SECURITY_INFO

Bits Description
0-1 Authentication (0 = AES_CMAC, 1 = PKC_RSA)
2 Encryption (0 = DISABLE, 1 = ENABLE)
3 Fuse encryption (0 = DISABLE, 1 = ENABLE)
4-6 Fuse encryption select (0 = TEST_KEY, 1 = NVIDIA_KEY, 2 to 7 = OEM_KEY_0 to OEM_KEY_5)
7 SE atomic context save (0 = DISABLE, 1 = ENABLE)

Stores configuration values for the new boot security mechanism.

Mariko units have authentication set to PKC_RSA, encryption enabled, fuse encryption enabled and fuse encryption select set to OEM_KEY_0 (development units) or OEM_KEY_1 (production units).

Bitmap

The actual hardware fuses are stored in a bitmap and may be programmed through the fuse driver after enabling fuse programming.

Fuse numbers are relative to the start of the fuse bitmap where each element is a 4 byte word and has a redundant alias. A single fuse write operation must always write the same value to fuse_bitmap + ((fuse_number + 0) << 2) (PRIMARY_ALIAS) and fuse_bitmap + ((fuse_number + 1) << 2) (REDUNDANT_ALIAS). However, spare bits and all fuses afterwards in the fuse bitmap, no longer have a redundant alias.

Erista

Name Number Redundant number Bits
enable_fuse_program 0 1 0
disable_fuse_program 0 1 1
bypass_fuses 0 1 2
jtag_direct_access_disable 0 1 3
production_mode 0 1 4
jtag_secureid_valid 0 1 5
odm_lock 0 1 6-9
fa_mode 0 1 10
security_mode 0 1 11
arm_debug_dis 0 1 12
obs_dis 0 1 13
public_key0 10 11 30-31
public_key0 12 13 0-29
public_key1 12 13 30-31
public_key1 14 15 0-29
public_key2 14 15 30-31
public_key2 16 17 0-29
public_key3 16 17 30-31
public_key3 18 19 0-29
public_key4 18 19 30-31
public_key4 20 21 0-29
public_key5 20 21 30-31
public_key5 22 23 0-29
public_key6 22 23 30-31
public_key6 24 25 0-29
public_key7 24 25 30-31
public_key7 26 27 0-29
private_key0 34 35 12-31
private_key0 36 37 0-11
private_key1 36 37 12-31
private_key1 38 39 0-11
private_key2 38 39 12-31
private_key2 40 41 0-11
private_key3 40 41 12-31
private_key3 42 43 0-11
private_key4 42 43 12-31
private_key4 44 45 0-11
boot_device_info 44 45 12-27
reserved_sw 44 45 28-31
reserved_sw 46 47 0-3
reserved_odm0 46 47 5-31
reserved_odm0 48 49 0-4
reserved_odm1 48 49 5-31
reserved_odm1 50 51 0-4
reserved_odm2 50 51 5-31
reserved_odm2 52 53 0-4
reserved_odm3 52 53 5-31
reserved_odm3 54 55 0-4
reserved_odm4 54 55 5-31
reserved_odm4 56 57 0-4
reserved_odm5 56 57 5-31
reserved_odm5 58 59 0-4
reserved_odm6 58 59 5-31
reserved_odm6 60 61 0-4
reserved_odm7 60 61 5-31
reserved_odm7 62 63 0-4
kfuse_privkey_ctrl 64 65 13-14
package_info 64 65 15-18
opt_vendor_code 64 65 19-22
opt_fab_code 64 65 23-28
opt_lot_code_0 64 65 29-31
opt_lot_code_0 66 67 0-28
opt_lot_code_1 66 67 29-31
opt_lot_code_1 68 69 0-24
opt_wafer_id 68 69 25-30
opt_x_coordinate 68 69 31
opt_x_coordinate 70 71 0-7
opt_y_coordinate 70 71 8-16
opt_sec_debug_en 70 71 17
opt_ops_reserved 70 71 18-23
sata_calib 70 71 24-25
opt_priv_sec_en 90 91 8
pkc_disable 90 91 9
fuse2tsec_debug_disable 90 91 10
secure_provision_index 90 91 24-27
secure_provision_info 90 91 28-29
spare_bit_0 100 None 16
spare_bit_1 100 None 17
spare_bit_2 100 None 18
spare_bit_3 100 None 19
spare_bit_4 100 None 20
spare_bit_5 100 None 21
spare_bit_6 100 None 22
spare_bit_7 100 None 23
spare_bit_8 100 None 24
spare_bit_9 100 None 25
spare_bit_10 100 None 26
spare_bit_11 100 None 27
spare_bit_12 100 None 28
spare_bit_13 100 None 29
spare_bit_14 100 None 30
spare_bit_15 100 None 31
spare_bit_16 101 None 16
spare_bit_17 101 None 17
spare_bit_18 101 None 18
spare_bit_19 101 None 19
spare_bit_20 101 None 20
spare_bit_21 101 None 21
spare_bit_22 101 None 22
spare_bit_23 101 None 23
spare_bit_24 101 None 24
spare_bit_25 101 None 25
spare_bit_26 101 None 26
spare_bit_27 101 None 27
spare_bit_28 101 None 28
spare_bit_29 101 None 29
spare_bit_30 101 None 30
spare_bit_31 101 None 31
aid 103 None 2-31
aid 104 None 0-1
reshift_records 106 None 0-192
irom_patch 112 None 0-2560

reserved_odm6

Used for anti-downgrade control.

reserved_odm7

Used for anti-downgrade control.

irom_patch

Bootrom patches are burned to the hardware fuse bitmap using a specific format (see ipatch decoder). The bootrom reads these fuses in order to initialize the IPATCH hardware, which allows overriding data returned for code and data fetches done by BPMP.

The following represents the patch data dumped from a Switch console:

RAM:00000000 ; =============== S U B R O U T I N E =======================================
RAM:00000000
RAM:00000000
RAM:00000000 irom_svc_dispatch
RAM:00000000   STMFD   SP!, {R0-R2}                  ; ipatches (new):
RAM:00000000                                         ;  0: 0x0b57df00 0x001016ae 0x0000df00 : svc #0x00 (offset 0x48)
RAM:00000000                                         ;  1: 0x1820df22 0x00103040 0x0000df22 : svc #0x22 (offset 0x8c)
RAM:00000000                                         ;  2: 0x3797df26 0x00106f2e 0x0000df26 : svc #0x26 (offset 0x94)
RAM:00000000                                         ;  3: 0x3b4d2100 0x0010769a 0x00002100 : movs r1, #0x00
RAM:00000000                                         ;  4: 0x042bdf2c 0x00100856 0x0000df2c : svc #0x2c (offset 0xa0)
RAM:00000000                                         ;  5: 0x37aadf42 0x00106f54 0x0000df42 : svc #0x42 (offset 0xcc)
RAM:00000000                                         ;  6: 0x0972df4b 0x001012e4 0x0000df4b : svc #0x4b (offset 0xde)
RAM:00000000                                         ;  7: 0x2293df54 0x00104526 0x0000df54 : svc #0x54 (offset 0xf0)
RAM:00000000                                         ;  8: 0x21fadf5d 0x001043f4 0x0000df5d : svc #0x5d (offset 0x102)
RAM:00000000                                         ;  9: 0xbba2ac57 0x00117744 0x0000ac57 : data
RAM:00000000                                         ; 10: 0xbbac3d19 0x00117758 0x00003d19 : data
RAM:00000000                                         ; 11: 0x1e952001 0x00103d2a 0x00002001 : movs r0, #0x01
RAM:00000000                                         ; 
RAM:00000000                                         ; ipatches (old):
RAM:00000000                                         ;  0: 0x0b57df00 0x001016ae 0x0000df00 : svc #0x00 (offset 0x48)
RAM:00000000                                         ;  1: 0x1820df22 0x00103040 0x0000df22 : svc #0x22 (offset 0x8c)
RAM:00000000                                         ;  2: 0x3797df26 0x00106f2e 0x0000df26 : svc #0x26 (offset 0x94)
RAM:00000000                                         ;  3: 0x7d9e2000 0x0010fb3c 0x00002000 : movs r0, #0x00
RAM:00000000                                         ;  4: 0x042bdf2c 0x00100856 0x0000df2c : svc #0x2c (offset 0xa0)
RAM:00000000                                         ;  5: 0x37aadf42 0x00106f54 0x0000df42 : svc #0x42 (offset 0xcc)
RAM:00000000                                         ;  6: 0x0972df4b 0x001012e4 0x0000df4b : svc #0x4b (offset 0xde)
RAM:00000000                                         ;  7: 0x2293df54 0x00104526 0x0000df54 : svc #0x54 (offset 0xf0)
RAM:00000000                                         ;  8: 0x21fadf5d 0x001043f4 0x0000df5d : svc #0x5d (offset 0x102)
RAM:00000000                                         ;  9: 0xbba2ac57 0x00117744 0x0000ac57 : data
RAM:00000000                                         ; 10: 0xbbac3d19 0x00117758 0x00003d19 : data
RAM:00000000                                         ; 11: 0x1e952001 0x00103d2a 0x00002001 : movs r0, #0x01
RAM:00000004   MOV     R2, LR
RAM:00000008   SUB     R2, R2, #2
RAM:0000000C   LDR     R2, [R2]
RAM:00000010   AND     R2, R2, #0xFF
RAM:00000014   MOV     R2, R2,LSL#1
RAM:00000018   LDR     R0, =0x1007B0
RAM:0000001C   LDR     R1, =0x1007F8
RAM:00000020   SUB     R1, R1, R0
RAM:00000024   LDR     R0, =0x40004C30
RAM:00000028   ADD     R0, R0, R1
RAM:0000002C   ADD     R2, R2, R0
RAM:00000030   ORR     R2, R2, #1
RAM:00000034   LDMFD   SP!, {R0,R1}
RAM:00000038   BX      R2
RAM:00000038 ; End of function irom_svc_dispatch
RAM:00000038
RAM:00000038 ; ---------------------------------------------------------------------------
RAM:0000003C dword_3C DCD 0x1007B0                   ; DATA XREF: irom_svc_dispatch+18↑r
RAM:00000040 dword_40 DCD 0x1007F8                   ; DATA XREF: irom_svc_dispatch+1C↑r
RAM:00000044 dword_44 DCD 0x40004C30                 ; DATA XREF: irom_svc_dispatch+24↑r
RAM:00000048   CODE16
RAM:00000048
RAM:00000048 ; =============== S U B R O U T I N E =======================================
RAM:00000048
RAM:00000048
RAM:00000048 sub_48
RAM:00000048   MOVS    R2, #0                        ; 0: 0x0b57df00 0x001016ae 0x0000df00 : svc #0x00 (offset 0x48)
RAM:0000004A   MVNS    R2, R2
RAM:0000004C   LDR     R1, =0x60006410
RAM:0000004E   STR     R2, [R1,#0x30]
RAM:00000050   STR     R2, [R1,#0x38]
RAM:00000052   LDR     R1, =0x600060F8
RAM:00000054   STR     R2, [R1]
RAM:00000056   STR     R2, [R1,#4]
RAM:00000058   LDR     R1, =0x60006284
RAM:0000005A   STR     R2, [R1]
RAM:0000005C   STR     R2, [R1,#0x18]
RAM:0000005E   ADDS    R1, #0x80
RAM:00000060   ADDS    R1, #0x1C
RAM:00000062   STR     R2, [R1]
RAM:00000064   STR     R2, [R1,#8]
RAM:00000066   STR     R2, [R1,#0x10]
RAM:00000068   ADDS    R1, #0x80
RAM:0000006A   STR     R2, [R1]
RAM:0000006C   STR     R2, [R1,#4]
RAM:0000006E   LDR     R1, =0x60006554
RAM:00000070   STR     R2, [R1]
RAM:00000072   MOVS    R2, #0xA0000000
RAM:00000076   LDR     R1, =0x60006148
RAM:00000078   STR     R2, [R1]
RAM:0000007A   ADDS    R1, #0x38 ; '8'
RAM:0000007C   STR     R2, [R1]
RAM:0000007E   MOVS    R2, #0xE0000000
RAM:00000082   LDR     R1, =0x600066A0
RAM:00000084   STR     R2, [R1]
RAM:00000086   MOVS    R1, #0
RAM:00000088   MOVS    R0, #0xE
RAM:0000008A   B       pop_r2_mov_pc_lr
RAM:0000008A ; End of function sub_48
RAM:0000008A
RAM:0000008C
RAM:0000008C ; =============== S U B R O U T I N E =======================================
RAM:0000008C
RAM:0000008C
RAM:0000008C sub_8C
RAM:0000008C   LDR     R0, [R1,#0x18]                ; 1: 0x1820df22 0x00103040 0x0000df22 : svc #0x22 (offset 0x8c)
RAM:0000008E   MOVS    R2, #1
RAM:00000090   ORRS    R0, R2
RAM:00000092   B       pop_r2_mov_pc_lr
RAM:00000092 ; End of function sub_8C
RAM:00000092
RAM:00000094
RAM:00000094 ; =============== S U B R O U T I N E =======================================
RAM:00000094
RAM:00000094
RAM:00000094 sub_94
RAM:00000094   LDR     R2, [R4,#0x50]                ; 2: 0x3797df26 0x00106f2e 0x0000df26 : svc #0x26 (offset 0x94)
RAM:00000096   ADDS    R2, R2, #2
RAM:00000098   STR     R2, [R4,#0x50]
RAM:0000009A   SUBS    R1, #0x80
RAM:0000009C   STR     R1, [R4,#0x34]
RAM:0000009E   B       pop_r2_mov_pc_lr
RAM:0000009E ; End of function sub_94
RAM:0000009E
RAM:000000A0
RAM:000000A0 ; =============== S U B R O U T I N E =======================================
RAM:000000A0
RAM:000000A0
RAM:000000A0 sub_A0
RAM:000000A0
RAM:000000A0 ; FUNCTION CHUNK AT RAM:00000148 SIZE 00000004 BYTES
RAM:000000A0
RAM:000000A0   MOVS    R0, #0x70000000               ; 4: 0x042bdf2c 0x00100856 0x0000df2c : svc #0x2c (offset 0xa0)
RAM:000000A4   LDR     R6, =dword_7000EF14
RAM:000000A6   LDR     R2, =dword_7000E5B4
RAM:000000A8   LDR     R2, [R2]
RAM:000000AA   CMP     R2, #0
RAM:000000AC   BEQ     loc_B4
RAM:000000AE   LDR     R2, [R6]
RAM:000000B0   STR     R2, [R0,#8]
RAM:000000B2   B       loc_BC
RAM:000000B4 ; ---------------------------------------------------------------------------
RAM:000000B4
RAM:000000B4 loc_B4                                  ; CODE XREF: sub_A0+C↑j
RAM:000000B4   LDR     R2, [R0,#8]
RAM:000000B6   LSRS    R0, R0, #0x12
RAM:000000B8   ORRS    R2, R0
RAM:000000BA   STR     R2, [R6]
RAM:000000BC
RAM:000000BC loc_BC                                  ; CODE XREF: sub_A0+12↑j
RAM:000000BC   LDR     R6, =dword_7000E9C0
RAM:000000BE   LDR     R0, [R6]
RAM:000000C0   MOVS    R2, #0x4000
RAM:000000C4   ORRS    R2, R0
RAM:000000C6   STR     R2, [R6]
RAM:000000C8   LDR     R0, [R5,#0x10]
RAM:000000CA   B       pop_r2_mov_pc_lr
RAM:000000CA ; End of function sub_A0
RAM:000000CA
RAM:000000CC
RAM:000000CC ; =============== S U B R O U T I N E =======================================
RAM:000000CC
RAM:000000CC
RAM:000000CC sub_CC
RAM:000000CC   MOVS    R2, #0xF000000                ; 5: 0x37aadf42 0x00106f54 0x0000df42 : svc #0x42 (offset 0xcc)
RAM:000000D0   BICS    R1, R2
RAM:000000D2   STR     R1, [R4,#0x10]
RAM:000000D4   LDR     R1, [R4,#0x50]
RAM:000000D6   MOVS    R2, #7
RAM:000000D8   BICS    R1, R2
RAM:000000DA   STR     R1, [R4,#0x50]
RAM:000000DC   B       pop_r2_mov_pc_lr
RAM:000000DC ; End of function sub_CC
RAM:000000DC
RAM:000000DE
RAM:000000DE ; =============== S U B R O U T I N E =======================================
RAM:000000DE
RAM:000000DE
RAM:000000DE sub_DE
RAM:000000DE   LDR     R2, =dword_7000FA9C           ; 6: 0x0972df4b 0x001012e4 0x0000df4b : svc #0x4b (offset 0xde)
RAM:000000E0   LDR     R2, [R2]
RAM:000000E2   LSRS    R2, R2, #8
RAM:000000E4   LSLS    R2, R2, #1
RAM:000000E6   LDR     R1, [R4]
RAM:000000E8   BICS    R1, R2
RAM:000000EA   STR     R1, [R4]
RAM:000000EC   CMP     R0, #0
RAM:000000EE   B       pop_r2_mov_pc_lr
RAM:000000EE ; End of function sub_DE
RAM:000000EE
RAM:000000F0
RAM:000000F0 ; =============== S U B R O U T I N E =======================================
RAM:000000F0
RAM:000000F0
RAM:000000F0 sub_F0
RAM:000000F0
RAM:000000F0 arg_0=  0
RAM:000000F0
RAM:000000F0   LDR     R0, =0x400049F0               ; 7: 0x2293df54 0x00104526 0x0000df54 : svc #0x54 (offset 0xf0)
RAM:000000F2   LDR     R2, [R0]
RAM:000000F4   STR     R2, [SP,#arg_0]
RAM:000000F6   LDR     R0, =0x40010000
RAM:000000F8   LSRS    R2, R2, #17
RAM:000000FA   BEQ     pop_r2_mov_pc_lr              ; if ([0x400049F0] >> 17) == 0) {
RAM:000000FA                                         ;   r2 = [0x400049F0];
RAM:000000FA                                         ; } else {
RAM:000000FC   LDR     R0, =APBDEV_PMC_CNTRL_0
RAM:000000FE   STR     R4, [R0]                      ;  write APBDEV_PMC_CNTRL
RAM:00000100
RAM:00000100 loc_100                                 ; CODE XREF: sub_F0:loc_100↓j
RAM:00000100   B       loc_100                       ;  hang
RAM:00000100 ; End of function sub_F0                ; }
RAM:00000100
RAM:00000102
RAM:00000102 ; =============== S U B R O U T I N E =======================================
RAM:00000102
RAM:00000102
RAM:00000102 sub_102
RAM:00000102
RAM:00000102 arg_0=  0
RAM:00000102
RAM:00000102   LDR     R2, =0x40010220               ; 8: 0x21fadf5d 0x001043f4 0x0000df5d : svc #0x5d (offset 0x102)
RAM:00000104   STR     R2, [SP,#arg_0]               ; set r2 retval = [0x40010220]
RAM:00000106   LDR     R2, [R2,#0x18]
RAM:00000108   ADDS    R0, #0xFC
RAM:0000010A   STR     R2, [R0,#0x1C]                ; [r0+0x118] = [0x40010220 + 0x18]
RAM:0000010C   B       pop_r2_mov_pc_lr
RAM:0000010C ; End of function sub_102
RAM:0000010C
RAM:0000010C ; ---------------------------------------------------------------------------
RAM:0000010E   DCB    0
RAM:0000010F   DCB    0
RAM:00000110 off_110 DCD 0x60006410                  ; DATA XREF: sub_48+4↑r
RAM:00000114 off_114 DCD 0x600060F8                  ; DATA XREF: sub_48+A↑r
RAM:00000118 off_118 DCD 0x60006284                  ; DATA XREF: sub_48+10↑r
RAM:0000011C off_11C DCD 0x60006554                  ; DATA XREF: sub_48+26↑r
RAM:00000120 off_120 DCD 0x60006148                  ; DATA XREF: sub_48+2E↑r
RAM:00000124 off_124 DCD 0x600066A0                  ; DATA XREF: sub_48+3A↑r
RAM:00000128 off_128 DCD dword_7000EF14              ; DATA XREF: sub_A0+4↑r
RAM:0000012C off_12C DCD dword_7000E5B4              ; DATA XREF: sub_A0+6↑r
RAM:00000130 off_130 DCD dword_7000E9C0              ; DATA XREF: sub_A0:loc_BC↑r
RAM:00000134 off_134 DCD dword_7000FA9C              ; DATA XREF: sub_DE↑r
RAM:00000138 off_138 DCD 0x400049F0                  ; DATA XREF: sub_F0↑r
RAM:0000013C dword_13C DCD 0x40010000                ; DATA XREF: sub_F0+6↑r
RAM:00000140 off_140 DCD APBDEV_PMC_CNTRL_0          ; DATA XREF: sub_F0+C↑r
RAM:00000144 off_144 DCD 0x40010220                  ; DATA XREF: sub_102↑r
RAM:00000148 ; ---------------------------------------------------------------------------
RAM:00000148 ; START OF FUNCTION CHUNK FOR sub_A0
RAM:00000148
RAM:00000148 pop_r2_mov_pc_lr                        ; CODE XREF: sub_48+42↑j
RAM:00000148                                         ; sub_8C+6↑j ...
RAM:00000148   POP     {R2}
RAM:0000014A   MOV     PC, LR
RAM:0000014A ; END OF FUNCTION CHUNK FOR sub_A0

The last 4 patches are exclusive to the Switch, while the remaining ones are often included in most Tegra210 based devices.

IROM patch 0

This patch configures clock enables and clock gate overrides for new hardware.

 u32 CLK_ENB_H_SET = 0x60006328;
 u32 CLK_ENB_L_SET = 0x60006320;
 u32 CLK_ENB_U_SET = 0x60006330; 
 u32 CLK_ENB_V_SET = 0x60006440;
 u32 CLK_ENB_W_SET = 0x60006448;
 u32 CLK_ENB_X_SET = 0x60006284;
 u32 CLK_ENB_Y_SET = 0x6000629C;
 u32 LVL2_CLK_GATE_OVRA = 0x600060F8;
 u32 LVL2_CLK_GATE_OVRB = 0x600060FC;
 u32 LVL2_CLK_GATE_OVRC = 0x600063A0;
 u32 LVL2_CLK_GATE_OVRD = 0x600063A4;
 u32 LVL2_CLK_GATE_OVRE = 0x60006554;
 u32 CLK_SOURCE_VI = 0x60006148;
 u32 CLK_SOURCE_HOST1X = 0x60006180;
 u32 CLK_SOURCE_NVENC = 0x600066A0; 

 // Set all clock enables and overrides
 *(u32 *)CLK_ENB_V_SET = 0xFFFFFFFF;
 *(u32 *)CLK_ENB_W_SET = 0xFFFFFFFF;
 *(u32 *)LVL2_CLK_GATE_OVRA = 0xFFFFFFFF;
 *(u32 *)LVL2_CLK_GATE_OVRB = 0xFFFFFFFF;
 *(u32 *)CLK_ENB_X_SET = 0xFFFFFFFF;
 *(u32 *)CLK_ENB_Y_SET = 0xFFFFFFFF;
 *(u32 *)CLK_ENB_L_SET = 0xFFFFFFFF;
 *(u32 *)CLK_ENB_H_SET = 0xFFFFFFFF;
 *(u32 *)CLK_ENB_U_SET = 0xFFFFFFFF;
 *(u32 *)LVL2_CLK_GATE_OVRC = 0xFFFFFFFF;
 *(u32 *)LVL2_CLK_GATE_OVRD = 0xFFFFFFFF;
 *(u32 *)LVL2_CLK_GATE_OVRE = 0xFFFFFFFF;

 // Set VI, HOST1X and NVENC clock sources to CLK_M
 *(u32 *)CLK_SOURCE_VI = 0xA0000000;
 *(u32 *)CLK_SOURCE_HOST1X = 0xA0000000;
 *(u32 *)CLK_SOURCE_NVENC = 0xE0000000;

 /*
     Untranslated instructions:

     MOVS    R1, #0
     MOVS    R0, #0xE
 */
 
 return;

IROM patch 1

This patch sets APBDEV_PMC_SCRATCH190_0 to 0x01, which LP0 resume code expects.

 u32 APBDEV_PMC_SCRATCH190_0 = 0x7000EC18;
 u32 pmc_scratch190_val = *(u32 *)APBDEV_PMC_SCRATCH190_0;
 
 return (pmc_scratch190_val | 0x01);

IROM patch 2

This patch adjusts USB configurations.

 u32 USB1_UTMIP_SPARE_CFG0_0 = 0x7D000834;
 u32 USB1_UTMIP_BIAS_CFG2_0 = 0x7D000850;
 
 // Increase UTMIP_HSSQUELCH_LEVEL_NEW by 0x02
 *(u32 *)USB1_UTMIP_BIAS_CFG2_0 += 0x02;

 // Clear FUSE_HS_IREF_CAP_CFG
 *(u32 *)USB1_UTMIP_SPARE_CFG0_0 = ((*(u32 *)USB1_UTMIP_SPARE_CFG0_0 & ~(0x118)) - 0x80);
 
 return;

IROM patch 3

This patch ensures that waiting on PRC_PENDING from the XUSB_DEV register T_XUSB_DEV_XHCI_PORTSC never fails.

In the second batch of patched units (FUSE_OPT_FT_REV set to revision 7.0) this patch has been replaced with a fix for CVE-2018-6242 (arbitrary copy when handling USB control requests in RCM). By setting R1 to 0 at address 0x0010769A in the bootrom, the upper 8 bits of the USB control request's wLength field are cleared out, effectively limiting the request's size to a maximum of 255 bytes.

IROM patch 4

This patch allows backing up and restoring strapping options for warmboot.

 u32 APBDEV_PMC_SCRATCH0_0 = 0x7000E450;
 u32 APBDEV_PMC_RST_STATUS_0 = 0x7000E5B4;
 u32 APBDEV_PMC_SEC_DISABLE8_0 = 0x7000E9C0;
 u32 APBDEV_PMC_SECURE_SCRATCH111_0 = 0x7000EF14;
 u32 APB_MISC_PP_STRAPPING_OPT_A_0 = 0x70000008; 

 u32 reset_status = *(u32 *)APBDEV_PMC_RST_STATUS_0;

 // Check for regular power on
 if (reset_status == 0)
 {    
     // Set all buttons in RCM_STRAPS and backup to PMC scratch
     *(u32 *)APBDEV_PMC_SECURE_SCRATCH111_0 = (*(u32 *)APB_MISC_PP_STRAPPING_OPT_A_0 | 0x1C00);
 }
 else
 {
     // Restore strapping options from PMC scratch
     *(u32 *)APB_MISC_PP_STRAPPING_OPT_A_0 = *(u32 *)APBDEV_PMC_SECURE_SCRATCH111_0;
 }

 // Disable write access to APBDEV_PMC_SECURE_SCRATCH111_0
 *(u32 *)APBDEV_PMC_SEC_DISABLE8_0 |= 0x4000;
 
 return *(u32 *)APBDEV_PMC_SCRATCH0_0;

IROM patch 5

This patch adjusts USB configurations.

 u32 USB1_UTMIP_HSRX_CFG0_0 = 0x7D000810;
 u32 USB1_UTMIP_BIAS_CFG2_0 = 0x7D000850;

 // Clear UTMIP_IDLE_WAIT, UTMIP_ELASTIC_LIMIT and UTMIP_PCOUNT_UPDN_DIV,
 // and set UTMIP_IDLE_WAIT to 0x11 and UTMIP_ELASTIC_LIMIT to 0x10 
 *(u32 *)USB1_UTMIP_HSRX_CFG0_0 = ((*(u32 *)USB1_UTMIP_HSRX_CFG0_0 & ~(0xF8000) + 0x88000 & ~(0x7C00) + 0x4000) & ~(0xF000000));
 
 // Clear UTMIP_HSSQUELCH_LEVEL_NEW
 *(u32 *)USB1_UTMIP_BIAS_CFG2_0 &= ~(0x07);
 
 return;

IROM patch 6

This patch allows controlling the debug authentication configuration using a fuse.

 u32 FUSE_ODM_INFO = 0x7000FA9C;

 u32 odm_info = *(u32 *)FUSE_ODM_INFO;
 debug_auth_override_val = ((odm_info >> 0x08) << 0x01);

 // Override debug authentication value stored in IRAM
 *(u32 *)0x400028E4 &= ~(debug_auth_override_val);

 /*
     Untranslated instructions:
 
     CMP     R0, #0
 */
 
 return;

IROM patch 7

This patch prevents overflowing IRAM (0x40010000) when copying the warmboot binary from DRAM.

 u32 APBDEV_PMC_CNTRL_0 = 0x7000E400;
 
 u32 warmboot_header_addr = 0x400049F0;
 u32 warmboot_bin_size = *(u32 *)warmboot_bin_header_addr;
 
 // Invalid warmboot binary size
 if (warmboot_size >> 0x11)
 {
     // Assert MAIN_RST
     // 0x40004BF0 comes from R4 and the bootrom doesn't bother to change it
     *(u32 *)APBDEV_PMC_CNTRL_0 = 0x40004BF0;

     // Deadlock
     while(1);
 }
 
 /*
     Untranslated instructions:
 
     LDR     R0, =0x40010000
     LDR     R2, [warmboot_bin_header_addr]
 */

 return;

IROM patch 8

This patch sets the correct warmboot binary entrypoint address for RSA signature verification, which would be done in DRAM instead of IRAM without this patch.

 u32 warmboot_addr_ptr = 0x40010238;
 u32 warmboot_entry_addr_ptr = 0x40004C28;

 *(u32 *)warmboot_entry_addr_ptr = *(u32 *)warmboot_addr_ptr;

 /*
     Untranslated instructions:
 
     LDR     R2, [warmboot_addr_ptr]
 */
 
 return;

IROM patches 9 and 10

These patches modify the 256-bit Secure Provisioning AES key with index 0x3A.

IROM patch 11

This patch forces the value of SE_TZRAM_SECURITY to be 0x01 instead of restoring it from the saved SE context.

Mariko

Name Number Redundant number Bits
enable_fuse_program 0 1 0
disable_fuse_program 0 1 1
bypass_fuses 0 1 2
jtag_direct_access_disable 0 1 3
production_mode 0 1 4
jtag_secureid_valid 0 1 5
odm_lock 0 1 6-21
fa_mode 0 1 22
security_mode 0 1 23
arm_debug_dis 0 1 24
obs_dis 0 1 25
public_key0 64 65 15-31
public_key0 66 67 0-14
public_key1 66 67 15-31
public_key1 68 69 0-14
public_key2 68 69 15-31
public_key2 70 71 0-14
public_key3 70 71 15-31
public_key3 72 73 0-14
public_key4 72 73 15-31
public_key4 74 75 0-14
public_key5 74 75 15-31
public_key5 76 77 0-14
public_key6 76 77 15-31
public_key6 78 79 0-14
public_key7 78 79 15-31
public_key7 80 81 0-14
private_key0 86 87 30-31
private_key0 88 89 0-29
private_key1 88 89 30-31
private_key1 90 91 0-29
private_key2 90 91 30-31
private_key2 92 93 0-29
private_key3 92 93 30-31
private_key3 94 95 0-29
private_key4 94 95 30-31
private_key4 96 97 0-29
boot_device_info 96 97 30-31
boot_device_info 98 99 0-13
reserved_sw 98 99 14-25
secure_provision_index 152 153 23-26
secure_provision_info 152 153 27-28
aid 165 None 2-31
aid 166 None 0-1
spare_bit_0 167 None 2
spare_bit_1 167 None 3
spare_bit_2 167 None 4
spare_bit_3 167 None 5
spare_bit_4 167 None 6
spare_bit_5 167 None 7
spare_bit_6 167 None 8
spare_bit_7 167 None 9
spare_bit_8 167 None 10
spare_bit_9 167 None 11
spare_bit_10 167 None 12
spare_bit_11 167 None 13
spare_bit_12 167 None 14
spare_bit_13 167 None 15
spare_bit_14 167 None 16
spare_bit_15 167 None 17
spare_bit_16 167 None 18
spare_bit_17 167 None 19
spare_bit_18 167 None 20
spare_bit_19 167 None 21
spare_bit_20 167 None 22
spare_bit_21 167 None 23
spare_bit_22 167 None 24
spare_bit_23 167 None 25
spare_bit_24 167 None 26
spare_bit_25 167 None 27
spare_bit_26 167 None 28
spare_bit_27 167 None 29
spare_bit_28 167 None 30
spare_bit_29 167 None 31
reshift_records 170 None 0-192
irom_patch 176 None 0-2560

irom_patch

RAM:00000000 ; =============== S U B R O U T I N E =======================================
RAM:00000000
RAM:00000000
RAM:00000000 irom_svc_dispatch
RAM:00000000   STMFD   SP!, {R0-R2}                  ; ipatches:
RAM:00000000                                         ;  0: 0x085bdf00 0x001010b6 0x0000df00 : svc #0x00 (offset 0x48)
RAM:00000000                                         ; 
RAM:00000000                                         ;  0: 0x12d3df06 0x001025a6 0x0000df06 : svc #0x06 (offset 0x54)
RAM:00000000                                         ;  1: 0x28144770 0x00105028 0x00004770 : bx lr
RAM:00000000                                         ;  2: 0x0fb72001 0x00101f6e 0x00002001 : movs r0, #0x01
RAM:00000000                                         ;  3: 0x692ddf15 0x0010d25a 0x0000df15 : svc #0x15 (offset 0x72)
RAM:00000000                                         ;  4: 0x436ddf1f 0x001086da 0x0000df1f : svc #0x1f (offset 0x86)
RAM:00000000                                         ;  5: 0x4376df23 0x001086ec 0x0000df23 : svc #0x23 (offset 0x8e)
RAM:00000000                                         ;  6: 0x4103df2b 0x00108206 0x0000df2b : svc #0x2b (offset 0x9e)
RAM:00000000                                         ;  7: 0x495c0060 0x001092b8 0x00000060 : lsls r0, r4, #1
RAM:00000000                                         ;  8: 0x62e3ef5b 0x0010c5c6 0x0000ef5b : svc #0x5b (offset 0xfe)
RAM:00000000                                         ;  9: 0x10d1df6a 0x001021a2 0x0000df6a : svc #0x6a (offset 0x11c)
RAM:00000004   MOV     R2, LR
RAM:00000008   SUB     R2, R2, #2
RAM:0000000C   LDR     R2, [R2]
RAM:00000010   AND     R2, R2, #0xFF
RAM:00000014   MOV     R2, R2,LSL#1
RAM:00000018   LDR     R0, =0x10022C
RAM:0000001C   LDR     R1, =0x100174
RAM:00000020   SUB     R1, R1, R0
RAM:00000024   LDR     R0, =0x40004164
RAM:00000028   ADD     R0, R0, R1
RAM:0000002C   ADD     R2, R2, R0
RAM:00000030   ORR     R2, R2, #1
RAM:00000034   LDMFD   SP!, {R0,R1}
RAM:00000038   BX      R2
RAM:00000038 ; End of function irom_svc_dispatch
RAM:00000038
RAM:00000038 ; ---------------------------------------------------------------------------
RAM:0000003C dword_3C        DCD 0x10022C            ; DATA XREF: irom_svc_dispatch+18↑r
RAM:00000040 dword_40        DCD 0x100174            ; DATA XREF: irom_svc_dispatch+1C↑r
RAM:00000044 dword_44        DCD 0x40004164          ; DATA XREF: irom_svc_dispatch+24↑r
RAM:00000048   CODE16
RAM:00000048
RAM:00000048 ; =============== S U B R O U T I N E =======================================
RAM:00000048
RAM:00000048
RAM:00000048 sub_48                                  ; 0: 0x085bdf00 0x001010b6 0x0000df00 : svc #0x00 (offset 0x48)
RAM:00000048   CMP     R5, #0xAF
RAM:0000004A   BNE     loc_4E
RAM:0000004C   MOVS    R5, #0xFF
RAM:0000004E
RAM:0000004E loc_4E                                  ; CODE XREF: sub_48+2↑j
RAM:0000004E   SUBS    R6, R5, #1
RAM:00000050
RAM:00000050 loc_50                                  ; CODE XREF: sub_54+18↓j
RAM:00000050                                         ; sub_72+12↓j ...
RAM:00000050   POP     {R2}
RAM:00000052   MOV     PC, LR
RAM:00000052 ; End of function sub_48
RAM:00000052
RAM:00000054
RAM:00000054 ; =============== S U B R O U T I N E =======================================
RAM:00000054
RAM:00000054
RAM:00000054 sub_54                                  ; 0: 0x12d3df06 0x001025a6 0x0000df06 : svc #0x06 (offset 0x54)
RAM:00000054   MOVS    R3, #7
RAM:00000056
RAM:00000056 loc_56                                  ; CODE XREF: sub_72+10↓j
RAM:00000056                                         ; sub_8E+E↓j
RAM:00000056   PUSH    {R0,R1,R3-R6}
RAM:00000058   LDR     R0, =0x4000FC20
RAM:0000005A   LDR     R1, =0x40040000
RAM:0000005C   LDR     R3, =0xEAFFFFFE
RAM:0000005E   MOVS    R4, R3
RAM:00000060   MOVS    R5, R3
RAM:00000062   ADDS    R6, R3, #0
RAM:00000064
RAM:00000064 loc_64                                  ; CODE XREF: sub_54+14↓j
RAM:00000064   STMIA   R0!, {R3-R6}
RAM:00000066   CMP     R0, R1
RAM:00000068   BCC     loc_64
RAM:0000006A   POP     {R0,R1,R3-R6}
RAM:0000006C   B       loc_50
RAM:0000006C ; End of function sub_54
RAM:0000006C
RAM:0000006E ; ---------------------------------------------------------------------------
RAM:0000006E ; START OF FUNCTION CHUNK FOR sub_8E
RAM:0000006E
RAM:0000006E loc_6E                                  ; CODE XREF: sub_8E+8↓j
RAM:0000006E   LDR     R0, =0x1002A0
RAM:00000070   BX      R0
RAM:00000070 ; END OF FUNCTION CHUNK FOR sub_8E
RAM:00000072
RAM:00000072 ; =============== S U B R O U T I N E =======================================
RAM:00000072
RAM:00000072
RAM:00000072 sub_72                                  ; 3: 0x692ddf15 0x0010d25a 0x0000df15 : svc #0x15 (offset 0x72)
RAM:00000072   MOVS    R2, #2
RAM:00000074   CMP     R0, #0x26 ; '&'
RAM:00000076   BLS     loc_7A
RAM:00000078   ADDS    R2, #0x50 ; 'P'
RAM:0000007A
RAM:0000007A loc_7A                                  ; CODE XREF: sub_72+4↑j
RAM:0000007A   MOV     R3, LR
RAM:0000007C   ADDS    R3, R3, R2
RAM:0000007E   MOV     LR, R3
RAM:00000080   CMP     R0, #0
RAM:00000082   BNE     loc_56
RAM:00000084   B       loc_50
RAM:00000084 ; End of function sub_72
RAM:00000084
RAM:00000086
RAM:00000086 ; =============== S U B R O U T I N E =======================================
RAM:00000086
RAM:00000086
RAM:00000086 sub_86                                  ; 4: 0x436ddf1f 0x001086da 0x0000df1f : svc #0x1f (offset 0x86)
RAM:00000086
RAM:00000086 arg_8   =  8
RAM:00000086
RAM:00000086   MOVS    R3, R0
RAM:00000088   LDR     R2, =0x5A55F0E1
RAM:0000008A   STR     R2, [SP,#arg_8]
RAM:0000008C   B       loc_50
RAM:0000008C ; End of function sub_86
RAM:0000008C
RAM:0000008E
RAM:0000008E ; =============== S U B R O U T I N E =======================================
RAM:0000008E
RAM:0000008E
RAM:0000008E sub_8E                                  ; 5: 0x4376df23 0x001086ec 0x0000df23 : svc #0x23 (offset 0x8e)
RAM:0000008E
RAM:0000008E arg_8   =  8
RAM:0000008E
RAM:0000008E ; FUNCTION CHUNK AT RAM:0000006E SIZE 00000004 BYTES
RAM:0000008E
RAM:0000008E   MOVS    R3, R0
RAM:00000090   LDR     R2, =0x5A55F0E1
RAM:00000092   LDR     R0, [SP,#arg_8]
RAM:00000094   CMP     R0, R2
RAM:00000096   BEQ     loc_6E
RAM:00000098   CMP     R0, #0
RAM:0000009A   BEQ     loc_50
RAM:0000009C   B       loc_56
RAM:0000009C ; End of function sub_8E
RAM:0000009C
RAM:0000009E
RAM:0000009E ; =============== S U B R O U T I N E =======================================
RAM:0000009E
RAM:0000009E
RAM:0000009E sub_9E                                  ; 6: 0x4103df2b 0x00108206 0x0000df2b : svc #0x2b (offset 0x9e)
RAM:0000009E   LDR     R0, =0x7000F900
RAM:000000A0   SUBS    R0, #0xD8
RAM:000000A2   MOVS    R2, #1
RAM:000000A4   STR     R2, [R0]
RAM:000000A6   LDR     R0, =0x7001231C
RAM:000000A8   LDR     R3, =0x7041231C
RAM:000000AA   MOVS    R1, #0xE0
RAM:000000AC   B       loc_B4
RAM:000000AE ; ---------------------------------------------------------------------------
RAM:000000AE
RAM:000000AE loc_AE                                  ; CODE XREF: sub_9E+2E↓j
RAM:000000AE   MOVS    R1, #0xF0
RAM:000000B0   B       loc_B4
RAM:000000B2 ; ---------------------------------------------------------------------------
RAM:000000B2
RAM:000000B2 loc_B2                                  ; CODE XREF: sub_9E+32↓j
RAM:000000B2   MOVS    R1, #0xC0
RAM:000000B4
RAM:000000B4 loc_B4                                  ; CODE XREF: sub_9E+E↑j
RAM:000000B4                                         ; sub_9E+12↑j
RAM:000000B4   MOVS    R4, #0
RAM:000000B6
RAM:000000B6 loc_B6                                  ; CODE XREF: sub_9E+28↓j
RAM:000000B6   MOVS    R2, #0
RAM:000000B8   STR     R1, [R0]
RAM:000000BA   STR     R2, [R0,#4]
RAM:000000BC   STR     R1, [R3]
RAM:000000BE   STR     R2, [R3,#4]
RAM:000000C0   ADDS    R1, #1
RAM:000000C2   ADDS    R4, #1
RAM:000000C4   CMP     R4, #7
RAM:000000C6   BLS     loc_B6
RAM:000000C8   LSRS    R1, R1, #4
RAM:000000CA   CMP     R1, #0xE
RAM:000000CC   BEQ     loc_AE
RAM:000000CE   CMP     R1, #0xF
RAM:000000D0   BEQ     loc_B2
RAM:000000D2   MOV     R5, LR
RAM:000000D4   MOVS    R0, #0
RAM:000000D6
RAM:000000D6 loc_D6                                  ; CODE XREF: sub_9E+56↓j
RAM:000000D6   MOVS    R1, #0xD
RAM:000000D8   MOVS    R2, #0
RAM:000000DA   MOVS    R3, #0xD
RAM:000000DC   PUSH    {R0-R3}
RAM:000000DE   LDR     R4, =0x40004164
RAM:000000E0   PUSH    {R2,R4}
RAM:000000E2   ADRL    R4, (loc_EC+1)
RAM:000000E6   MOV     LR, R4
RAM:000000E8   LDR     R4, =0x105A19
RAM:000000EA   BX      R4
RAM:000000EC
RAM:000000EC loc_EC                                  ; DATA XREF: sub_9E+44↑o
RAM:000000EC   ADD     SP, SP, #8
RAM:000000EE   POP     {R0-R3}
RAM:000000F0   ADDS    R0, #1
RAM:000000F2   CMP     R0, #1
RAM:000000F4   BEQ     loc_D6
RAM:000000F6   MOV     LR, R5
RAM:000000F8   LDR     R0, =0x4000FC20
RAM:000000FA   MOV     R8, R0
RAM:000000FC   B       loc_50
RAM:000000FC ; End of function sub_9E
RAM:000000FC
RAM:000000FE
RAM:000000FE ; =============== S U B R O U T I N E =======================================
RAM:000000FE
RAM:000000FE
RAM:000000FE sub_FE                                  ;  8: 0x62e3ef5b 0x0010c5c6 0x0000ef5b : svc #0x5b (offset 0xfe)
RAM:000000FE   POP     {R2}
RAM:00000100   MOV     R4, SP
RAM:00000102   SUBS    R4, R4, R0
RAM:00000104   BLS     loc_10C
RAM:00000106   CMP     R4, R2
RAM:00000108   BCS     loc_118
RAM:0000010A   B       loc_116
RAM:0000010C ; ---------------------------------------------------------------------------
RAM:0000010C
RAM:0000010C loc_10C                                 ; CODE XREF: sub_FE+6↑j
RAM:0000010C   LDR     R4, =0x4000BE68
RAM:0000010E   SUBS    R4, R4, R0
RAM:00000110   BLS     loc_118
RAM:00000112   CMP     R4, R2
RAM:00000114   BCS     loc_118
RAM:00000116
RAM:00000116 loc_116                                 ; CODE XREF: sub_FE+C↑j
RAM:00000116   ADDS    R2, R4, #0
RAM:00000118
RAM:00000118 loc_118                                 ; CODE XREF: sub_FE+A↑j
RAM:00000118                                         ; sub_FE+12↑j ...
RAM:00000118   SUBS    R3, R0, R1
RAM:0000011A   BX      LR
RAM:0000011A ; End of function sub_FE
RAM:0000011A
RAM:0000011C
RAM:0000011C ; =============== S U B R O U T I N E =======================================
RAM:0000011C
RAM:0000011C
RAM:0000011C sub_11C                                 ; 9: 0x10d1df6a 0x001021a2 0x0000df6a : svc #0x6a (offset 0x11c)
RAM:0000011C   SUBS    R3, #5
RAM:0000011E   MOVS    R2, #0xF0
RAM:00000120   BICS    R2, R3
RAM:00000122   B       loc_50
RAM:00000122 ; End of function sub_11C
RAM:00000122
RAM:00000122 ; ---------------------------------------------------------------------------
RAM:00000124 dword_124       DCD 0x4000FC20          ; DATA XREF: sub_54+4↑r
RAM:00000124                                         ; sub_9E+5A↑r
RAM:00000128 dword_128       DCD 0x40040000          ; DATA XREF: sub_54+6↑r
RAM:0000012C dword_12C       DCD 0xEAFFFFFE          ; DATA XREF: sub_54+8↑r
RAM:00000130 off_130         DCD 0x1002A0            ; DATA XREF: sub_8E:loc_6E↑r
RAM:00000134 dword_134       DCD 0x5A55F0E1          ; DATA XREF: sub_86+2↑r
RAM:00000134                                         ; sub_8E+2↑r
RAM:00000138 dword_138       DCD 0x7000F900          ; DATA XREF: sub_9E↑r
RAM:0000013C off_13C         DCD 0x7001231C          ; DATA XREF: sub_9E+8↑r
RAM:00000140 off_140         DCD 0x7041231C          ; DATA XREF: sub_9E+A↑r
RAM:00000144 dword_144       DCD 0x40004164          ; DATA XREF: sub_9E+40↑r
RAM:00000148 off_148         DCD 0x105A19            ; DATA XREF: sub_9E+4A↑r
RAM:0000014C dword_14C       DCD 0x4000BE68          ; DATA XREF: sub_FE:loc_10C↑r
RAM:0000014C ; RAM           ends

First IROM patch

This patch is applied to the bootrom IPATCH handling function so that more patches can be loaded from fuses.

 if (patch_start_addr == 0xAF) {
     patch_start_addr = 0xFF;
 }
 
 patch_start_addr--;
 
 return;

IROM patch 0

This patch initializes all unused IRAM memory to 0xEAFFFFFE (infinite loop instruction).

 /*
     Untranslated instructions:
 
     MOVS    R3, #7
     PUSH    {R0,R1,R3-R6}
 */
 
 for (u32 addr = 0x4000FC20; addr < 0x40040000; addr += 0x04) {
     *(u32 *)addr = 0xEAFFFFFE;
 }
 
 /*
     Untranslated instructions:
 
     POP     {R0,R1,R3-R6}
 */
 
 return;

IROM patch 1

This patch stubs the function responsible for disabling read access for the SE AES keyslots.

Due to a programming mistake, when loading the OEM AES keys the aforementioned function would be called with the wrong arguments. The patch prevents this by simply stubbing the function altogether, which is only acceptable because the Mariko's SE hardware already boots with keyslot reading permanently disabled.

IROM patch 2

This patch forces the function responsible for checking if SE context atomic save is enabled (by checking a fuse) to always return true.

Some Mariko units have been found to not have the relevant fuse bit (bit 7 in FUSE_BOOT_SECURITY_INFO) burned, so the patch serves as a workaround for this.

IROM patch 3

This patch forces a jump to the same routine used by IROM patch 0 if loading a bootloader failed.

By setting all IRAM memory from 0x4000FC20 to 0x40040000 to 0xEAFFFFFE, a bootloader that somehow failed validation is effectively erased from memory.

IROM patch 4

This patch stores a stack cookie (value 0x5A55F0E1) after a RCM message is received and before it's validated.

IROM patch 5

This patch checks the stack cookie stored by IROM patch 4 right after a RCM message is validated.

If the stack cookie's value is still 0x5A55F0E1, the bootrom jumps to a panic. If it changed to anything other than 0, the same routine used by IROM patch 0 is called. Presumably, this is an attempt at mitigating fault injection attacks against skipping the validation of RCM messages.

IROM patch 6

This patch sanitizes the crypto context right before receiving a RCM message.

 u32 FUSE_PRIVATEKEYDISABLE = 0x7000F828;
 u32 SE1_CRYPTO_KEYTABLE_ADDR = 0x7001231C;
 u32 SE2_CRYPTO_KEYTABLE_ADDR = 0x7041231C;
 u32 SE1_CRYPTO_KEYTABLE_DATA = 0x70012320;
 u32 SE2_CRYPTO_KEYTABLE_DATA = 0x70412320;
 
 // Hide the private key fuses
 *(u32 *)FUSE_PRIVATEKEYDISABLE = 0x1;
 
 u32 crypto_keytable_val = 0xE0;
 
 // Clear SE1/SE2 keyslot 0xE (contains the SBK)
 for (int i = 0; i < 0x7; i++) {
     *(u32 *)SE1_CRYPTO_KEYTABLE_ADDR = crypto_keytable_val;
     *(u32 *)SE1_CRYPTO_KEYTABLE_DATA = 0;
     *(u32 *)SE2_CRYPTO_KEYTABLE_ADDR = crypto_keytable_val;
     *(u32 *)SE2_CRYPTO_KEYTABLE_DATA = 0;
     crypto_keytable_val++;
 }
 
 crypto_keytable_val = 0xF0;
 
 // Clear SE1/SE2 keyslot 0xF (contains the SSK)
 for (int i = 0; i < 0x07; i++) {
     *(u32 *)SE1_CRYPTO_KEYTABLE_ADDR = crypto_keytable_val;
     *(u32 *)SE1_CRYPTO_KEYTABLE_DATA = 0;
     *(u32 *)SE2_CRYPTO_KEYTABLE_ADDR = crypto_keytable_val;
     *(u32 *)SE2_CRYPTO_KEYTABLE_DATA = 0;
     crypto_keytable_val++;
 }
 
 crypto_keytable_val = 0xC0;
 
 // Clear SE1/SE2 keyslot 0xC (contains the KEK)
 for (int i = 0; i < 0x7; i++) {
     *(u32 *)SE1_CRYPTO_KEYTABLE_ADDR = crypto_keytable_val;
     *(u32 *)SE1_CRYPTO_KEYTABLE_DATA = 0;
     *(u32 *)SE2_CRYPTO_KEYTABLE_ADDR = crypto_keytable_val;
     *(u32 *)SE2_CRYPTO_KEYTABLE_DATA = 0;
     crypto_keytable_val++;
 }
 
 u8 se_instance = 0;          // SE1
 u8 se_src_key_slot = 0xD;
 u8 se_src_key_size = 0;      // 128 bits
 u8 se_dst_key_slot = 0xD;
 u8 se_dst_key_size = 0;      // 128 bits
 u8 *se_src_key_data = 0x40004164;
 
 // Overwrite SE1 keyslot 0xD (contains the BEK)
 se_decrypt_key_into_key_slot(se_instance, se_src_key_slot, se_src_key_size, se_dst_key_slot, se_dst_key_size, se_src_key_data);
 
 se_instance = 1;             // SE2
 
 // Overwrite SE2 keyslot 0xD (contains the BEK)
 se_decrypt_key_into_key_slot(se_instance, se_src_key_slot, se_src_key_size, se_dst_key_slot, se_dst_key_size, se_src_key_data);
 
 /*
     Untranslated instructions:
 
     LDR     R0, =0x4000FC20
     MOV     R8, R0
 */
 
 return;

IROM patch 7

This patch doubles the maximum value passed to the function responsible for generating random numbers with the SE. These values are then used for randomizing the duration of wait loops scattered around the bootrom.

IROM patch 8

This patch forces memcpy to always fall outside of current stack limits.

IROM patch 9

This patch forces TZRAM to be cleared on any boot type (instead of clearing it only on coldboot).

Anti-downgrade

The first bootloader verifies FUSE_RESERVED_ODM7 to prevent downgrading. How many fuses are expected to be burnt depends the device's unit type as below.

System version Expected number of burnt fuses (production) Expected number of burnt fuses (development)
1.0.0 1 0
2.0.0-2.3.0 2 0
3.0.0 3 1
3.0.1-3.0.2 4 1
4.0.0-4.1.0 5 1
5.0.0-5.1.0 6 1
6.0.0-6.1.0 7 1
6.2.0 8 1
7.0.0-8.0.1 9 1
8.1.0 10 1
9.0.0-9.0.1 11 1
9.1.0-9.2.0 12 1
10.0.0-10.2.0 13 1
11.0.0-12.0.1 14 1
12.0.2-13.1.0 15 1
13.2.1-14.1.2 16 1
15.0.0-15.0.1 17 1
16.0.0-16.1.0 18 1
17.0.0-18.1.0 19 1
19.0.0-19.0.1 20 1

If too many fuses are burnt the bootloader will panic immediately.

If too few are burnt, the bootloader will enable fuse programming and write the expected value to fuses reserved_odm6 and reserved_odm7. Afterwards, fuse programming is disabled and the panic value 0x21 is written to PMC_SCRATCH200 register (0x7000EC40). Finally, the watchdog timer is initialized and programmed to force a reset.

On a subsequent boot, after the anti-downgrade fuses are checked again, the PMC_RST_STATUS register (0x7000E5B4) is checked and if set to 0x01 (watchdog reset) the PMC_SCRATCH200 register (0x7000EC40) will be checked for the panic value 0x21. PMC_RST_STATUS will only be set back to 0 (power on reset) if the fuse count matches the new expected value, otherwise the system will panic.