1
0
Fork 0
mirror of https://github.com/DarkMatterCore/nxdumptool.git synced 2024-11-26 20:22:17 +00:00
nxdumptool/source/nca.h
Pablo Curiel b71f0d7b87 Some more changes.
* Codestyle fixes.
* NCA contexts for NCAs with titlekey crypto will now be generated even if the ticket can't be retrieved, in order to be able to use ncaReadContentFile() with them.
* Moved aes128XtsNintendoCrypt() out of nca.c.
2020-07-05 20:10:07 -04:00

449 lines
18 KiB
C

/*
* nca.h
*
* Copyright (c) 2020, DarkMatterCore <pabloacurielz@gmail.com>.
*
* This file is part of nxdumptool (https://github.com/DarkMatterCore/nxdumptool).
*
* nxdumptool is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* nxdumptool is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#pragma once
#ifndef __NCA_H__
#define __NCA_H__
#include "tik.h"
#define NCA_HEADER_LENGTH 0x400
#define NCA_FS_HEADER_LENGTH 0x200
#define NCA_FS_HEADER_COUNT 4
#define NCA_FULL_HEADER_LENGTH (NCA_HEADER_LENGTH + (NCA_FS_HEADER_LENGTH * NCA_FS_HEADER_COUNT))
#define NCA_NCA0_MAGIC 0x4E434130 /* "NCA0" */
#define NCA_NCA2_MAGIC 0x4E434132 /* "NCA2" */
#define NCA_NCA3_MAGIC 0x4E434133 /* "NCA3" */
#define NCA_HIERARCHICAL_SHA256_LAYER_COUNT 2
#define NCA_IVFC_MAGIC 0x49564643 /* "IVFC" */
#define NCA_IVFC_LAYER_COUNT 7
#define NCA_IVFC_HASH_DATA_LAYER_COUNT 5
#define NCA_IVFC_BLOCK_SIZE(x) (1 << (x))
#define NCA_BKTR_MAGIC 0x424B5452 /* "BKTR" */
#define NCA_FS_ENTRY_BLOCK_SIZE 0x200
#define NCA_FS_ENTRY_BLOCK_OFFSET(x) ((u64)(x) * NCA_FS_ENTRY_BLOCK_SIZE)
#define NCA_AES_XTS_SECTOR_SIZE 0x200
#define NCA_NCA0_FS_HEADER_AES_XTS_SECTOR(x) (((x) - NCA_HEADER_LENGTH) >> 9)
typedef enum {
NcaDistributionType_Download = 0,
NcaDistributionType_GameCard = 1
} NcaDistributionType;
typedef enum {
NcaContentType_Program = 0,
NcaContentType_Meta = 1,
NcaContentType_Control = 2,
NcaContentType_Manual = 3,
NcaContentType_Data = 4,
NcaContentType_PublicData = 5
} NcaContentType;
typedef enum {
NcaKeyGenerationOld_100_230 = 0,
NcaKeyGenerationOld_300 = 2
} NcaKeyGenerationOld;
typedef enum {
NcaKeyAreaEncryptionKeyIndex_Application = 0,
NcaKeyAreaEncryptionKeyIndex_Ocean = 1,
NcaKeyAreaEncryptionKeyIndex_System = 2
} NcaKeyAreaEncryptionKeyIndex;
typedef struct {
u8 relstep;
u8 micro;
u8 minor;
u8 major;
} NcaSdkAddOnVersion;
/// 'NcaKeyGeneration_Current' will always point to the last known key generation value.
typedef enum {
NcaKeyGeneration_301_302 = 3,
NcaKeyGeneration_400_410 = 4,
NcaKeyGeneration_500_510 = 5,
NcaKeyGeneration_600_610 = 6,
NcaKeyGeneration_620 = 7,
NcaKeyGeneration_700_801 = 8,
NcaKeyGeneration_810_811 = 9,
NcaKeyGeneration_900_901 = 10,
NcaKeyGeneration_910_1004 = 11,
NcaKeyGeneration_Current = NcaKeyGeneration_910_1004
} NcaKeyGeneration;
typedef struct {
u32 start_block_offset; ///< Expressed in NCA_FS_ENTRY_BLOCK_SIZE blocks.
u32 end_block_offset; ///< Expressed in NCA_FS_ENTRY_BLOCK_SIZE blocks.
u8 enable_entry;
u8 reserved[0x7];
} NcaFsEntry;
typedef struct {
u8 hash[SHA256_HASH_SIZE];
} NcaFsHash;
typedef struct {
u8 key[0x10];
} NcaKey;
typedef enum {
NcaFsType_RomFs = 0,
NcaFsType_PartitionFs = 1
} NcaFsType;
typedef enum {
NcaHashType_Auto = 0,
NcaHashType_None = 1,
NcaHashType_HierarchicalSha256 = 2, ///< Used by NcaFsType_PartitionFs.
NcaHashType_HierarchicalIntegrity = 3 ///< Used by NcaFsType_RomFs.
} NcaHashType;
typedef enum {
NcaEncryptionType_Auto = 0,
NcaEncryptionType_None = 1,
NcaEncryptionType_AesXts = 2,
NcaEncryptionType_AesCtr = 3,
NcaEncryptionType_AesCtrEx = 4
} NcaEncryptionType;
typedef struct {
u64 offset;
u64 size;
} NcaHierarchicalSha256LayerInfo;
/// Used for NcaFsType_PartitionFs and NCA0 NcaFsType_RomFsRomFS.
typedef struct {
u8 master_hash[SHA256_HASH_SIZE];
u32 hash_block_size;
u32 layer_count;
NcaHierarchicalSha256LayerInfo hash_data_layer_info;
NcaHierarchicalSha256LayerInfo hash_target_layer_info;
} NcaHierarchicalSha256;
typedef struct {
u64 offset;
u64 size;
u32 block_size; ///< Use NCA_IVFC_BLOCK_SIZE to calculate the actual block size using this value.
u8 reserved[0x4];
} NcaHierarchicalIntegrityLayerInfo;
/// Used for NcaFsType_RomFs.
typedef struct {
u32 magic; ///< "IVFC".
u32 version;
u32 master_hash_size;
u32 layer_count;
NcaHierarchicalIntegrityLayerInfo hash_data_layer_info[NCA_IVFC_HASH_DATA_LAYER_COUNT];
NcaHierarchicalIntegrityLayerInfo hash_target_layer_info;
u8 signature_salt[0x20];
u8 master_hash[0x20];
} NcaHierarchicalIntegrity;
typedef struct {
union {
struct {
///< Used if hash_type == NcaHashType_HierarchicalSha256 (NcaFsType_PartitionFs and NCA0 NcaFsType_RomFs).
NcaHierarchicalSha256 hierarchical_sha256;
u8 reserved_1[0xB0];
};
struct {
///< Used if hash_type == NcaHashType_HierarchicalIntegrity (NcaFsType_RomFs).
NcaHierarchicalIntegrity hierarchical_integrity;
u8 reserved_2[0x18];
};
};
} NcaHashInfo;
typedef struct {
u32 magic; ///< "BKTR".
u32 bucket_count;
u32 entry_count;
u8 reserved[0x4];
} NcaBucketTreeHeader;
/// Only used for NcaEncryptionType_AesCtrEx (PatchRomFs).
typedef struct {
u64 indirect_offset;
u64 indirect_size;
NcaBucketTreeHeader indirect_header;
u64 aes_ctr_ex_offset;
u64 aes_ctr_ex_size;
NcaBucketTreeHeader aes_ctr_ex_header;
} NcaPatchInfo;
/// Format unknown.
typedef struct {
u8 unknown[0x30];
} NcaSparseInfo;
typedef struct {
u16 version;
u8 fs_type; ///< NcaFsType.
u8 hash_type; ///< NcaHashType.
u8 encryption_type; ///< NcaEncryptionType.
u8 reserved_1[0x3];
NcaHashInfo hash_info;
NcaPatchInfo patch_info;
union {
u8 section_ctr[0x8];
struct {
u32 generation;
u32 secure_value;
};
};
NcaSparseInfo sparse_info;
u8 reserved_2[0x88];
} NcaFsHeader;
typedef struct {
u8 main_signature[0x100]; ///< RSA-PSS signature over header with fixed key.
u8 acid_signature[0x100]; ///< RSA-PSS signature over header with key in NPDM.
u32 magic; ///< "NCA0" / "NCA2" / "NCA3".
u8 distribution_type; ///< NcaDistributionType.
u8 content_type; ///< NcaContentType.
u8 key_generation_old; ///< NcaKeyGenerationOld.
u8 kaek_index; ///< NcaKeyAreaEncryptionKeyIndex.
u64 content_size;
u64 program_id;
u32 content_index;
NcaSdkAddOnVersion sdk_addon_version;
u8 key_generation; ///< NcaKeyGeneration.
u8 main_signature_key_generation;
u8 reserved_1[0xE];
FsRightsId rights_id; ///< Used for titlekey crypto.
NcaFsEntry fs_entries[4]; ///< Start and end offsets for each NCA FS section.
NcaFsHash fs_hashes[4]; ///< SHA-256 hashes calculated over each NCA FS section header.
NcaKey encrypted_keys[4]; ///< Only the encrypted key at index #2 is used. The other three are zero filled before the key area is encrypted.
u8 reserved_2[0xC0];
NcaFsHeader fs_headers[4]; /// NCA FS section headers.
} NcaHeader;
typedef enum {
NcaVersion_Nca0 = 0,
NcaVersion_Nca2 = 1,
NcaVersion_Nca3 = 2
} NcaVersion;
typedef enum {
NcaFsSectionType_PartitionFs = 0, ///< NcaFsType_PartitionFs + NcaHashType_HierarchicalSha256.
NcaFsSectionType_RomFs = 1, ///< NcaFsType_RomFs + NcaHashType_HierarchicalIntegrity.
NcaFsSectionType_PatchRomFs = 2, ///< NcaFsType_RomFs + NcaHashType_HierarchicalIntegrity + NcaEncryptionType_AesCtrEx.
NcaFsSectionType_Nca0RomFs = 3, ///< NcaFsType_RomFs + NcaHashType_HierarchicalSha256 + NcaVersion_Nca0.
NcaFsSectionType_Invalid = 4
} NcaFsSectionType;
typedef struct {
bool enabled;
void *nca_ctx; ///< NcaContext. Used to perform NCA reads.
u8 section_num;
u64 section_offset;
u64 section_size;
u8 section_type; ///< NcaFsSectionType.
u8 encryption_type; ///< NcaEncryptionType.
NcaFsHeader *header;
u8 ctr[0x10]; ///< Used to update the AES CTR context IV based on the desired offset.
Aes128CtrContext ctr_ctx;
Aes128XtsContext xts_decrypt_ctx;
Aes128XtsContext xts_encrypt_ctx;
} NcaFsSectionContext;
typedef struct {
u8 storage_id; ///< NcmStorageId.
NcmContentStorage *ncm_storage; ///< Pointer to a NcmContentStorage instance. Used to read NCA data.
u64 gamecard_offset; ///< Used to read NCA data from a gamecard using a FsStorage instance when storage_id == NcmStorageId_GameCard.
NcmContentId content_id; ///< Also used to read NCA data.
char content_id_str[0x21];
u8 hash[0x20]; ///< Manually calculated (if needed).
char hash_str[0x41];
u8 format_version; ///< NcaVersion.
u8 content_type; ///< NcmContentType. Retrieved from NcmContentInfo.
u64 content_size; ///< Retrieved from NcmContentInfo.
u8 key_generation; ///< NcaKeyGenerationOld / NcaKeyGeneration. Retrieved from the decrypted header.
u8 id_offset; ///< Retrieved from NcmContentInfo.
bool rights_id_available;
bool titlekey_retrieved;
u8 titlekey[0x10];
bool dirty_header;
NcaHeader header;
NcaFsSectionContext fs_contexts[4];
NcaKey decrypted_keys[4];
} NcaContext;
typedef struct {
u64 offset; ///< New layer data offset (relative to the start of the NCA content file).
u64 size; ///< New layer data size.
u8 *data; ///< New layer data.
} NcaHashInfoLayerPatch;
typedef struct {
NcaHashInfoLayerPatch hash_data_layer_patch;
NcaHashInfoLayerPatch hash_target_layer_patch;
} NcaHierarchicalSha256Patch;
typedef struct {
NcaHashInfoLayerPatch hash_data_layer_patch[NCA_IVFC_HASH_DATA_LAYER_COUNT];
NcaHashInfoLayerPatch hash_target_layer_patch;
} NcaHierarchicalIntegrityPatch;
/// Functions to control the internal heap buffer used by NCA FS section crypto operations.
/// Must be called at startup.
bool ncaAllocateCryptoBuffer(void);
void ncaFreeCryptoBuffer(void);
/// Initializes a NCA context.
/// If 'storage_id' != NcmStorageId_GameCard, the 'ncm_storage' argument must point to a valid NcmContentStorage instance, previously opened using the same NcmStorageId value.
/// If 'storage_id' == NcmStorageId_GameCard, the 'hfs_partition_type' argument must be a valid GameCardHashFileSystemPartitionType value.
/// If the NCA holds a populated Rights ID field, and if the Ticket element pointed to by 'tik' hasn't been filled, ticket data will be retrieved.
/// If ticket data can't be retrieved, the context will still be initialized, but anything that involves working with plaintext FS section blocks won't be possible (e.g. ncaReadFsSection()).
bool ncaInitializeContext(NcaContext *out, u8 storage_id, NcmContentStorage *ncm_storage, u8 hfs_partition_type, const NcmContentInfo *content_info, Ticket *tik);
/// Reads raw encrypted data from a NCA using an input context, previously initialized by ncaInitializeContext().
/// Input offset must be relative to the start of the NCA content file.
bool ncaReadContentFile(NcaContext *ctx, void *out, u64 read_size, u64 offset);
/// Reads decrypted data from a NCA FS section using an input context.
/// Input offset must be relative to the start of the NCA FS section.
/// If dealing with Patch RomFS sections, this function should only be used when *not* reading BKTR AesCtrEx storage data. Use ncaReadAesCtrExStorageFromBktrSection() for that.
bool ncaReadFsSection(NcaFsSectionContext *ctx, void *out, u64 read_size, u64 offset);
/// Reads decrypted BKTR AesCtrEx storage data from a NCA Patch RomFS section using an input context and a AesCtrEx CTR value.
/// Input offset must be relative to the start of the NCA FS section.
bool ncaReadAesCtrExStorageFromBktrSection(NcaFsSectionContext *ctx, void *out, u64 read_size, u64 offset, u32 ctr_val);
/// Returns a pointer to a heap-allocated buffer used to encrypt the input plaintext data, based on the encryption type used by the input NCA FS section, as well as its offset and size.
/// Input offset must be relative to the start of the NCA FS section.
/// Output size and offset are guaranteed to be aligned to the AES sector size used by the encryption type from the FS section.
/// Output offset is relative to the start of the NCA content file, making it easier to use the output encrypted block to seamlessly replace data while dumping a NCA.
/// This function isn't compatible with Patch RomFS sections.
void *ncaGenerateEncryptedFsSectionBlock(NcaFsSectionContext *ctx, const void *data, u64 data_size, u64 data_offset, u64 *out_block_size, u64 *out_block_offset);
/// Generates HierarchicalSha256 FS section patch data, which can be used to replace NCA data in content dumping operations.
/// Input offset must be relative to the start of the HierarchicalSha256 hash target layer (actual underlying FS).
/// Bear in mind that this function recalculates both the NcaHashInfo block master hash and the NCA FS header hash from the NCA header, and enables the 'dirty_header' flag from the NCA context.
/// As such, this function is not designed to generate more than one patch per HierarchicalSha256 FS section.
bool ncaGenerateHierarchicalSha256Patch(NcaFsSectionContext *ctx, const void *data, u64 data_size, u64 data_offset, NcaHierarchicalSha256Patch *out);
/// Cleanups a previously generated NcaHierarchicalSha256Patch.
NX_INLINE void ncaFreeHierarchicalSha256Patch(NcaHierarchicalSha256Patch *patch)
{
if (!patch) return;
if (patch->hash_data_layer_patch.data) free(patch->hash_data_layer_patch.data);
if (patch->hash_target_layer_patch.data) free(patch->hash_target_layer_patch.data);
memset(patch, 0, sizeof(NcaHierarchicalSha256Patch));
}
/// Generates HierarchicalIntegrity FS section patch data, which can be used to replace NCA data in content dumping operations.
/// Input offset must be relative to the start of the HierarchicalIntegrity hash target layer (actual underlying FS).
/// Bear in mind that this function recalculates both the NcaHashInfo block master hash and the NCA FS header hash from the NCA header, and enables the 'dirty_header' flag from the NCA context.
/// As such, this function is not designed to generate more than one patch per HierarchicalIntegrity FS section.
bool ncaGenerateHierarchicalIntegrityPatch(NcaFsSectionContext *ctx, const void *data, u64 data_size, u64 data_offset, NcaHierarchicalIntegrityPatch *out);
/// Cleanups a previously generated NcaHierarchicalIntegrityPatch.
NX_INLINE void ncaFreeHierarchicalIntegrityPatch(NcaHierarchicalIntegrityPatch *patch)
{
if (!patch) return;
for(u8 i = 0; i < (NCA_IVFC_HASH_DATA_LAYER_COUNT + 1); i++)
{
NcaHashInfoLayerPatch *layer_patch = (i < NCA_IVFC_HASH_DATA_LAYER_COUNT ? &(patch->hash_data_layer_patch[i]) : &(patch->hash_target_layer_patch));
if (layer_patch->data) free(layer_patch->data);
}
memset(patch, 0, sizeof(NcaHierarchicalIntegrityPatch));
}
bool ncaEncryptKeyArea(NcaContext *nca_ctx);
bool ncaEncryptHeader(NcaContext *ctx);
/// Miscellaneous functions.
NX_INLINE void ncaConvertNcmContentSizeToU64(const u8 *size, u64 *out)
{
if (!size || !out) return;
*out = 0;
memcpy(out, size, 6);
}
NX_INLINE void ncaConvertU64ToNcmContentSize(const u64 *size, u8 *out)
{
if (size && out) memcpy(out, size, 6);
}
NX_INLINE void ncaSetDownloadDistributionType(NcaContext *ctx)
{
if (!ctx || ctx->header.distribution_type == NcaDistributionType_Download) return;
ctx->header.distribution_type = NcaDistributionType_Download;
ctx->dirty_header = true;
}
NX_INLINE void ncaWipeRightsId(NcaContext *ctx)
{
if (!ctx || !ctx->rights_id_available) return;
memset(&(ctx->header.rights_id), 0, sizeof(FsRightsId));
ctx->dirty_header = true;
}
NX_INLINE bool ncaValidateHierarchicalSha256Offsets(NcaHierarchicalSha256 *hierarchical_sha256, u64 section_size)
{
if (!hierarchical_sha256 || !section_size || !hierarchical_sha256->hash_block_size || hierarchical_sha256->layer_count != NCA_HIERARCHICAL_SHA256_LAYER_COUNT) return false;
for(u8 i = 0; i < NCA_HIERARCHICAL_SHA256_LAYER_COUNT; i++)
{
NcaHierarchicalSha256LayerInfo *layer_info = (i == 0 ? &(hierarchical_sha256->hash_data_layer_info) : &(hierarchical_sha256->hash_target_layer_info));
if (layer_info->offset >= section_size || !layer_info->size || (layer_info->offset + layer_info->size) > section_size) return false;
}
return true;
}
NX_INLINE bool ncaValidateHierarchicalIntegrityOffsets(NcaHierarchicalIntegrity *hierarchical_integrity, u64 section_size)
{
if (!hierarchical_integrity || !section_size || __builtin_bswap32(hierarchical_integrity->magic) != NCA_IVFC_MAGIC || !hierarchical_integrity->master_hash_size || \
hierarchical_integrity->layer_count != NCA_IVFC_LAYER_COUNT) return false;
for(u8 i = 0; i < (NCA_IVFC_HASH_DATA_LAYER_COUNT + 1); i++)
{
NcaHierarchicalIntegrityLayerInfo *layer_info = (i < NCA_IVFC_HASH_DATA_LAYER_COUNT ? &(hierarchical_integrity->hash_data_layer_info[i]) : &(hierarchical_integrity->hash_target_layer_info));
if (layer_info->offset >= section_size || !layer_info->size || !layer_info->block_size || (layer_info->offset + layer_info->size) > section_size) return false;
}
return true;
}
#endif /* __NCA_H__ */