# Difference between revisions of "RSA Registers"

(→RSA_MOD: Note about attack to read RSA_EXPFIFO indirectly) |
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+ | = Overview = | ||

+ | |||

+ | The RSA module is essentially a hardware-accelerated modular exponentiation engine. It is specially optimized for RSA applications, so its behavior can be incoherent when RSA's invariants are broken. | ||

+ | |||

+ | === Observed edge cases === | ||

+ | * if 2 divides mod, output == 0 | ||

+ | |||

= Registers = | = Registers = | ||

{| class="wikitable" border="1" | {| class="wikitable" border="1" | ||

Line 46: | Line 53: | ||

| [[#RSA_EXPFIFO|RSA_EXPFIFO]] | | [[#RSA_EXPFIFO|RSA_EXPFIFO]] | ||

| 0x1000B200 | | 0x1000B200 | ||

− | | | + | | 0x100 (can handle u32 writes to any aligned position in the FIFO) |

| | | | ||

|- | |- | ||

Line 71: | Line 78: | ||

|- | |- | ||

| 1 | | 1 | ||

− | | | + | | Interrupt enable (1=enable, 0=disable) |

|- | |- | ||

| 4-7 | | 4-7 | ||

Line 77: | Line 84: | ||

|- | |- | ||

| 8 | | 8 | ||

− | | Endianness (1=Little endian, 0=Big endian) | + | | Endianness (1=Little endian, 0=Big endian). Affects RSA_EXPFIFO, RSA_MOD, and RSA_TXT. |

|- | |- | ||

| 9 | | 9 | ||

− | | Word order (1=Normal order, 0=Reversed order) | + | | Word order (1=Normal order, 0=Reversed order). Affects RSA_MOD and RSA_TXT. |

|} | |} | ||

Line 117: | Line 124: | ||

| Key write-protect, this bit is RW. (0 = no protection, 1 = protected) | | Key write-protect, this bit is RW. (0 = no protection, 1 = protected) | ||

|- | |- | ||

− | | 30- | + | | 2 |

+ | | Key read-protect, this bit is RW. (0 = no protection, 1 = protected) | ||

+ | |- | ||

+ | | 30-3 | ||

| ? | | ? | ||

|- | |- | ||

| 31 | | 31 | ||

− | | | + | | Key slot protect. Makes all other bits in this reg read-only until reset |

|} | |} | ||

## Latest revision as of 00:34, 6 February 2021

# Overview[edit]

The RSA module is essentially a hardware-accelerated modular exponentiation engine. It is specially optimized for RSA applications, so its behavior can be incoherent when RSA's invariants are broken.

### Observed edge cases[edit]

- if 2 divides mod, output == 0

# Registers[edit]

Old3DS | Name | Address | Width | Used by |
---|---|---|---|---|

Yes | RSA_CNT | 0x1000B000 | 0x04 | |

Yes | RSA_? | 0x1000B0F0 | 0x04 | |

Yes | RSA_SLOT0 | 0x1000B100 | 0x10 | |

Yes | RSA_SLOT1 | 0x1000B110 | 0x10 | |

Yes | RSA_SLOT2 | 0x1000B120 | 0x10 | |

Yes | RSA_SLOT3 | 0x1000B130 | 0x10 | |

Yes | RSA_EXPFIFO | 0x1000B200 | 0x100 (can handle u32 writes to any aligned position in the FIFO) | |

Yes | RSA_MOD | 0x1000B400 | 0x100 | |

Yes | RSA_TXT | 0x1000B800 | 0x100 |

## RSA_CNT[edit]

Bit | Description |
---|---|

0 | Start (1=Enable/Busy, 0=Idle) |

1 | Interrupt enable (1=enable, 0=disable) |

4-7 | Keyslot (Bit6-7 don't actually affect the keyslot) |

8 | Endianness (1=Little endian, 0=Big endian). Affects RSA_EXPFIFO, RSA_MOD, and RSA_TXT. |

9 | Word order (1=Normal order, 0=Reversed order). Affects RSA_MOD and RSA_TXT. |

## RSA_SLOT[edit]

Name | Offset | Width |
---|---|---|

RSA_SLOTCNT | 0x0 | 0x4 |

RSA_SLOTSIZE | 0x4 | 0x4 |

? | 0x8 | 0x4 |

? | 0xC | 0x4 |

## RSA_SLOTCNT[edit]

Bits | Description |
---|---|

0 | Key status (1=Key has been set, 0=Key has not been set yet) |

1 | Key write-protect, this bit is RW. (0 = no protection, 1 = protected) |

2 | Key read-protect, this bit is RW. (0 = no protection, 1 = protected) |

30-3 | ? |

31 | Key slot protect. Makes all other bits in this reg read-only until reset |

Before writing RSA_EXPFIFO/RSA_MOD, bit0 here should be cleared when bit31 is already clear. Otherwise, the ARM9 will hang when attempting to write to RSA_EXPFIFO.

## RSA_SLOTSIZE[edit]

This contains the RSA size for this slot, in words. Normally this is 0x40 for RSA-2048.

## RSA_EXPFIFO[edit]

The 0x100-byte private or public exponent is written to this write-only FIFO.

## RSA_MOD[edit]

The RSA key modulus for the selected keyslot can be written here. When writing the RSA modulus, the modulus must align with the end of the register area.

Writing to RSA_MOD does not change the exponent written with RSA_EXPFIFO. An attack based on the Pohlig-Hellman algorithm exists to "read" the contents of RSA_EXPFIFO as a result (see 3DS System Flaws).

## RSA_TXT[edit]

The RSA signature can be written here, and the data read from here is the message. When writing the RSA signature, the signature must be prepended with zeroes until it is a multiple of 8 bytes, and the end of the signature must align with the end of the register area.

The PKCS message padding must be manually checked by software, as hardware will only do raw RSA operations.

## Keyslots usage[edit]

Keyslot | Description |
---|---|

0 | Arbitrary |

1 | CXI access desc (following the exheader) |

2-3 | Initialized by the ARM9 bootrom, but not used by any of the FIRMs. It's unknown what the ARM9 bootrom uses these for, if anything. |