NCA

From Nintendo Switch Brew
Revision as of 21:04, 18 January 2022 by Myster-Tee (talk | contribs)
Jump to navigation Jump to search

NCA means «Nintendo Content Archive».

The entire raw NCAs are encrypted.

The only known area which is not encrypted in the raw NCA is the logo section, when the NCA includes that section. Everything else documented on this page is for the plaintext version of that data.

Encryption

The first 0xC00 bytes are encrypted with AES-XTS with sector size 0x200 with a non-standard "tweak" (endianness is reversed, see here), this encrypted data is an 0x400 NCA header + an 0x200 header for each section in the section table.

For pre-1.0.0 "NCA2" NCAs, the first 0x400 byte are encrypted the same way as in NCA3. However, each section header is individually encrypted as though it were sector 0, instead of the appropriate sector as in NCA3.

Header

Offset Size Description
0x0 0x100 RSA-2048 signature over the header (data from 0x200 to 0x400) using a fixed key
0x100 0x100 RSA-2048 signature over the header (data from 0x200 to 0x400) using a key from NPDM (or zeroes if not a program)
0x200 0x4 Magicnum "NCA3" ("NCA2", "NCA1" or "NCA0" for pre-1.0.0 NCAs)
0x204 0x1 DistributionType (0x00 = System NCA, 0x01 = Gamecard NCA)
0x205 0x1 ContentType (0x00 = Program, 0x01 = Meta, 0x02 = Control, 0x03 = Manual, 0x04 = Data, 0x05 = PublicData)
0x206 0x1 KeyGenerationOld (0x00 = 1.0.0, 0x01 = Unused, 0x02 = 3.0.0)
0x207 0x1 KeyAreaEncryptionKeyIndex (0x00 = Application, 0x01 = Ocean, 0x02 = System)
0x208 0x8 ContentSize
0x210 0x8 ProgramId
0x218 0x4 ContentIndex
0x21C 0x4 SdkAddonVersion (used in "FS_ACCESS: { sdk_version: {byte3}.{byte2}.{byte1}, ..." with byte0 set to 0 and compared with a required minimum value: 0x000B0000)
0x220 0x1 KeyGeneration (0x03 = 3.0.1, 0x04 = 4.0.0, 0x05 = 5.0.0, 0x06 = 6.0.0, 0x07 = 6.2.0, 0x08 = 7.0.0, 0x09 = 8.1.0, 0x0A = 9.0.0, 0x0B = 9.1.0, 0x0C = 12.1.0, 0x0D = 13.0.0, 0xFF = Invalid)
0x221 0x1 [9.0.0+] Header1SignatureKeyGeneration (0 or 1)
0x222 0xE Reserved
0x230 0x10 RightsId
0x240 0x10 * 4 Array of FsEntry
0x280 0x20 * 4 Array of SHA256 hashes (over each FsHeader)
0x300 0x10 * 4 EncryptedKeyArea

When the above KeyGenerationOld field is 0x2 on >= v3.0, different {crypto/keydata} is used for the sections' data. With system content, this is used with every ncatype except ncatype0. The only other exception is {data-content} for the firm titles: this is required in order for older-system-versions to install it.

KeyGeneration 0x3 (with KeyGenerationOld set to 0x2) is used for all 3.0.1 sysmodules and the System_Version_Title. With 3.0.2, all updated titles use the crypto from 3.0.1 for non-ncatype0, except for firm {data-content}. In some cases various game content uses the above newer crypto as well.

KeyGeneration is always MasterKeyVersion + 1, except for generations 0 and 1 which are both version 0.

The keyindex passed to <key-generation-related code> is determined as follows:

  • Pre-3.0.0: The KeyAreaEncryptionKeyIndex field (0x207) is passed directly.
  • 3.0.0+: It's determined using the KeyAreaEncryptionKeyIndex field (0x207) and the KeyGenerationOld field (0x206). The latter field must be 0, 1 or 2. In each ncahdr_keyindex block, it executes "if(ncahdr_x206>=3)<panic>", but that won't trigger due to the earlier check. The end result is basically the same as pre-3.0.0, except when ncahdr_x206 == 0x2, final_index is new_base_index+ncahdr_keyindex. Actual implementation loads index from u32_array[ncahdr_crypto_type], where the address of u32_array is different for each ncahdr_keyindex.
  • 3.0.1+: The dedicated range check for the KeyGenerationOld field (0x206) was removed, since the updated code no longer needs it. The output from a function masked with 0xFF is now used instead of ncahdr_x206. The range check for that field was changed from {ncahdr_x206 check with panic described above}, to "if(index>=4)final_index=10;"(skips accessing the array and uses 10 directly). The arrays were updated with an additional entry: final_index=v301_base_index+ncahdr_keyindex.
    • The keydata for the above index10 is not(?) known to be initialized.
    • The new function called by the code described above does:
    • if(ncahdr_x206 < ncahdr_x220){ret = ncahdr_x220; } else { ret = ncahdr_x206; } return ret;

FsEntry

Offset Size Description
0x0 0x4 StartOffset (in Media Units which are 0x200 bytes)
0x4 0x4 EndOffset (in Media Units which are 0x200 bytes)
0x8 0x4 Reserved
0xC 0x4 Reserved

FsHeader

Offset Size Description
0x0 0x2 Version (always 2)
0x2 0x1 FsType (0 = RomFs, 1 = PartitionFs)
0x3 0x1 HashType (0 = Auto, 2 = HierarchicalSha256, 3 = HierarchicalIntegrity)
0x4 0x1 EncryptionType (0 = Auto, 1 = None, 2 = AesCtrOld, 3 = AesCtr, 4 = AesCtrEx)
0x5 0x3 Padding
0x8 0xF8 HashInfo
0x100 0x40 PatchInfo (only used with game updates RomFs)
0x140 0x4 Generation
0x144 0x4 SecureValue
0x148 0x30 SparseInfo (only used in sections with sparse storage)
0x178 0x88 Reserved

The FsHeader for each section is at absoluteoffset+0x400+(sectionid*0x200), where sectionid corresponds to the index used with the entry/hash tables.

HashInfo

This contains information specific to the hash type in use.

HierarchicalSha256

Offset Size Description
0x0 0x20 SHA256 hash over the hash-table at section-start+0 with the below hash-table size
0x20 0x4 Block size in bytes
0x24 0x4 Must be 0x2
0x28 0x8 Offset of hash-table (normally zero)
0x30 0x8 Size of hash-table
0x38 0x8 Offset relative to section-start where the PFS0 header is located
0x40 0x8 Actual byte-size of the PFS0 filesystem relative to the PFS0 header
0x48 0xB0 Reserved

HierarchicalIntegrity

Offset Size Description
0x0 0x4 Magicnum "IVFC"
0x4 0x4 Magic Number (0x20000)
0xC 0x4 Master hash size?
0x10 0x4 Usually 7? Unknown, could be related to total number of levels maybe?
0x14 0x8 Level 1 offset
0x1C 0x8 Level 1 size
0x20 0x4 Level 1 block size (in log2)
0x24 0x4 Reserved
0x28 0x8 Level 2 offset
0x30 0x8 Level 2 size
0x38 0x4 Level 2 block size (in log2)
0x3C 0x4 Reserved
0x40 0x8 Level 3 offset
0x48 0x8 Level 3 size
0x50 0x4 Level 3 block size (in log2)
0x54 0x4 Reserved
0x58 0x8 Level 4 offset
0x60 0x8 Level 4 size
0x68 0x4 Level 4 block size (in log2)
0x6C 0x4 Reserved
0x70 0x8 Level 5 offset
0x78 0x8 Level 5 size
0x80 0x4 Level 5 block size (in log2)
0x84 0x4 Reserved
0x88 0x8 Level 6 offset
0x90 0x8 Level 6 size
0x98 0x4 Level 6 block size (in log2)
0x9C 0x4 Reserved
0xA0 0x20 Reserved
0xC0 0x20 Hash

PatchInfo

Offset Size Description
0x0 0x8 Offset
0x8 0x8 Size
0x10 0x4 Magicnum "BKTR"
0x14 0x4 u32, must be <=1.
0x18 0x4 s32, must be >=1.
0x1C 0x4
0x20 0x20 Same as the above 0x20-bytes except with different data.

The above byte-offsets are relative to the start of the section-data.

The two sections specified by the two BKTR entries are usually(?) at the very end of the section data(section_endoffset-{size of BKTR sections}).

RomFs Patching

The PatchInfo section enables combining data from an update NCA with the RomFs from a base NCA to create a single patched RomFS image.

The first BKTR entry describes how to map regions of the two RomFs images to create the patched RomFs. It has the following format:

Offset Size Description
0x0 0x4 Padding/Unused?
0x4 0x4 Number of Buckets
0x8 0x8 Total Size of the Virtual RomFS Image
0x10 0x3FF0 Base Virtual Offset for each Bucket (u64s, padded with 0s until end)
0x4000 0x4000*X Relocation Buckets

Where relocation buckets are as follows:

Offset Size Description
0x0 0x4 Padding/Unused?
0x4 0x4 Number of Entries
0x8 0x8 End offset for this Bucket
0x10 0x3FF0 Relocation Entries

Where relocation entries are as follows:

Offset Size Description
0x0 0x8 Address in Patched RomFs
0x8 0x8 Address in Source RomFs
0x10 0x4 1=Is from Patch RomFS, 0=Is from Base RomFS

The second BKTR entry describes the subsections within the Patch RomFs. It has the following format:

Offset Size Description
0x0 0x4 Padding/Unused?
0x4 0x4 Number of Buckets
0x8 0x8 Total Size of the Physical Patch Image
0x10 0x3FF0 Base Physical Offset for each Bucket (u64s, padded with 0s until end)
0x4000 0x4000*X Subsection Buckets

Where subsection buckets are as follows:

Offset Size Description
0x0 0x4 Padding/Unused?
0x4 0x4 Number of Entries
0x8 0x8 End offset for this Bucket
0x10 0x3FF0 Subsection Entries

Where subsection entries are as follows:

Offset Size Description
0x0 0x8 Address in Patch RomFs
0x8 0x4 Padding/Unused?
0xC 0x4 Value for subsection AES-CTR

Official code assumes the relocation entries are sorted, and performs a binary search when determining where to read from. Each subsection in the Patch RomFs has its CTR calculated separately from the others based on the value in its entry (the BKTR entries use normal crypto). Thus decrypting a Patch RomFS requires decrypting and parsing the BKTR entries before anything else.

Logo Section

This is a PFS0.

See here for the mounted-FS logo contents.

ExeFS Section

This is a PFS0.

See here for mounted-FS ExeFS contents.

Game Updates

The section-data for ncatype1 RomFS section(section1) uses section-crypto-type 0x4.

Game updates also contain multiple ncatype6 content, which contain "section0_pfs0/fragment". Some of these are just NCAs, unknown for the rest(presumably NCAs with additional crypto?). The first ncatype6 content fragment file has a NDV0 header, with the NCA starting at offset 0x44.

PFS0

Offset Size Description
{Hash-table offset from superblock} {Hash-table size from superblock} Table of SHA256 hashes.
{Hash-table <offset+size> from superblock} Zeros for alignment to {alignment size}.
{PFS0 offset from superblock} {PFS0 size from superblock} The actual PFS0.

This is the FS which has magicnum "PFS0" at header+0. This is very similar to HFS0. A tool for extracting this FS is available here.

The hash table is hashes for every {Block size from superblock} starting at the PFS0 header. The size used for the last hash is {PFS0 filesystem size from superblock} - offset_relativeto_header.

See also the PFS0 superblock above.

Offset Size Description
0x0 0x4 Magicnum "PFS0"
0x4 0x4 Number of files
0x8 0x4 Size of the string table
0xC 0x4 Zero/Reserved
0x10 X File Entry Table
0x10 + X Y String Table
0x10 + X + Y Z Raw File Data

Where File Entry Table consists of Number of Files FileEntries:

Offset Size Description
0x0 0x8 Offset of file in Data
0x8 0x8 Size of file in Data
0x10 0x4 Offset of filename in String Table
0x14 0x4 Normally zero?