/* * bktr.c * * Copyright (c) 2018-2020, SciresM. * Copyright (c) 2020-2023, DarkMatterCore . * * 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 of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * nxdumptool is distributed in the hope that 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 . */ #include "nxdt_utils.h" #include "bktr.h" #include "aes.h" /* Type definitions. */ typedef struct { u64 offset; u32 stride; } BucketTreeStorageNodeOffset; typedef struct { BucketTreeStorageNodeOffset start; u32 count; u32 index; } BucketTreeStorageNode; typedef struct { BucketTreeNodeHeader header; u64 start; } BucketTreeEntrySetHeader; NXDT_ASSERT(BucketTreeEntrySetHeader, BKTR_NODE_HEADER_SIZE + 0x8); typedef struct { BucketTreeContext *bktr_ctx; BucketTreeEntrySetHeader entry_set; u32 entry_index; void *entry; } BucketTreeVisitor; typedef struct { void *buffer; u64 offset; u64 size; u64 virtual_offset; u32 ctr_val; bool aes_ctr_ex_crypt; u8 parent_storage_type; ///< BucketTreeStorageType. } BucketTreeSubStorageReadParams; /* Global variables. */ #if LOG_LEVEL <= LOG_LEVEL_ERROR static const char *g_bktrStorageTypeNames[] = { [BucketTreeStorageType_Indirect] = "Indirect", [BucketTreeStorageType_AesCtrEx] = "AesCtrEx", [BucketTreeStorageType_Compressed] = "Compressed", [BucketTreeStorageType_Sparse] = "Sparse" }; #endif /* Function prototypes. */ #if LOG_LEVEL <= LOG_LEVEL_ERROR static const char *bktrGetStorageTypeName(u8 storage_type); #endif static bool bktrInitializeIndirectStorageContext(BucketTreeContext *out, NcaFsSectionContext *nca_fs_ctx, bool is_sparse); static bool bktrGetIndirectStorageEntryExtents(BucketTreeVisitor *visitor, u64 offset, BucketTreeIndirectStorageEntry *out_cur_entry, u64 *out_next_entry_offset); static bool bktrReadIndirectStorage(BucketTreeVisitor *visitor, void *out, u64 read_size, u64 offset); static bool bktrInitializeAesCtrExStorageContext(BucketTreeContext *out, NcaFsSectionContext *nca_fs_ctx); static bool bktrGetAesCtrExStorageEntryExtents(BucketTreeVisitor *visitor, u64 offset, BucketTreeAesCtrExStorageEntry *out_cur_entry, u64 *out_next_entry_offset); static bool bktrReadAesCtrExStorage(BucketTreeVisitor *visitor, void *out, u64 read_size, u64 offset); static bool bktrGetCompressedStorageEntryExtents(BucketTreeVisitor *visitor, u64 offset, BucketTreeCompressedStorageEntry *out_cur_entry, u64 *out_next_entry_offset); static bool bktrReadCompressedStorage(BucketTreeVisitor *visitor, void *out, u64 read_size, u64 offset); static bool bktrReadSubStorage(BucketTreeSubStorage *substorage, BucketTreeSubStorageReadParams *params); NX_INLINE void bktrInitializeSubStorageReadParams(BucketTreeSubStorageReadParams *out, void *buffer, u64 offset, u64 size, u64 virtual_offset, u32 ctr_val, bool aes_ctr_ex_crypt, u8 parent_storage_type); static bool bktrVerifyBucketInfo(NcaBucketInfo *bucket, u64 node_size, u64 entry_size, u64 *out_node_storage_size, u64 *out_entry_storage_size); static bool bktrValidateTableOffsetNode(const BucketTreeTable *table, u64 node_size, u64 entry_size, u32 entry_count, u64 *out_start_offset, u64 *out_end_offset); NX_INLINE bool bktrVerifyNodeHeader(const BucketTreeNodeHeader *node_header, u32 node_index, u64 node_size, u64 entry_size); static u64 bktrQueryNodeStorageSize(u64 node_size, u64 entry_size, u32 entry_count); static u64 bktrQueryEntryStorageSize(u64 node_size, u64 entry_size, u32 entry_count); NX_INLINE u32 bktrGetEntryCount(u64 node_size, u64 entry_size); NX_INLINE u32 bktrGetOffsetCount(u64 node_size); NX_INLINE u32 bktrGetEntrySetCount(u64 node_size, u64 entry_size, u32 entry_count); NX_INLINE u32 bktrGetNodeL2Count(u64 node_size, u64 entry_size, u32 entry_count); NX_INLINE const void *bktrGetNodeArray(const BucketTreeNodeHeader *node_header); NX_INLINE const u64 *bktrGetOffsetNodeArray(const BucketTreeOffsetNode *offset_node); NX_INLINE const u64 *bktrGetOffsetNodeBegin(const BucketTreeOffsetNode *offset_node); NX_INLINE const u64 *bktrGetOffsetNodeEnd(const BucketTreeOffsetNode *offset_node); static bool bktrFindStorageEntry(BucketTreeContext *ctx, u64 virtual_offset, BucketTreeVisitor *out_visitor); static bool bktrGetTreeNodeEntryIndex(const u64 *start_ptr, const u64 *end_ptr, u64 virtual_offset, u32 *out_index); static bool bktrGetEntryNodeEntryIndex(const BucketTreeNodeHeader *node_header, u64 entry_size, u64 virtual_offset, u32 *out_index); static bool bktrFindEntrySet(BucketTreeContext *ctx, u32 *out_index, u64 virtual_offset, u32 node_index); static const BucketTreeNodeHeader *bktrGetTreeNodeHeader(BucketTreeContext *ctx, u32 node_index); NX_INLINE u32 bktrGetEntrySetIndex(BucketTreeContext *ctx, u32 node_index, u32 offset_index); static bool bktrFindEntry(BucketTreeContext *ctx, BucketTreeVisitor *out_visitor, u64 virtual_offset, u32 entry_set_index); static const BucketTreeNodeHeader *bktrGetEntryNodeHeader(BucketTreeContext *ctx, u32 entry_set_index); NX_INLINE u64 bktrGetEntryNodeEntryOffset(u64 entry_set_offset, u64 entry_size, u32 entry_index); NX_INLINE u64 bktrGetEntryNodeEntryOffsetByIndex(u32 entry_set_index, u64 node_size, u64 entry_size, u32 entry_index); NX_INLINE bool bktrIsExistL2(BucketTreeContext *ctx); NX_INLINE bool bktrIsExistOffsetL2OnL1(BucketTreeContext *ctx); static void bktrInitializeStorageNode(BucketTreeStorageNode *out, u64 entry_size, u32 entry_count); static void bktrStorageNodeFind(BucketTreeStorageNode *storage_node, const BucketTreeNodeHeader *node_header, u64 virtual_offset); NX_INLINE BucketTreeStorageNodeOffset bktrStorageNodeOffsetAdd(BucketTreeStorageNodeOffset *ofs, u64 value); NX_INLINE const u64 bktrStorageNodeOffsetGetEntryVirtualOffset(const BucketTreeNodeHeader *node_header, const BucketTreeStorageNodeOffset *ofs); NX_INLINE bool bktrVisitorIsValid(BucketTreeVisitor *visitor); NX_INLINE bool bktrVisitorCanMoveNext(BucketTreeVisitor *visitor); static bool bktrVisitorMoveNext(BucketTreeVisitor *visitor); bool bktrInitializeContext(BucketTreeContext *out, NcaFsSectionContext *nca_fs_ctx, u8 storage_type) { if (!out || !nca_fs_ctx || !nca_fs_ctx->enabled || nca_fs_ctx->section_type >= NcaFsSectionType_Invalid || !nca_fs_ctx->nca_ctx || \ (nca_fs_ctx->nca_ctx->rights_id_available && !nca_fs_ctx->nca_ctx->titlekey_retrieved) || storage_type == BucketTreeStorageType_Compressed || \ storage_type >= BucketTreeStorageType_Count) { LOG_MSG_ERROR("Invalid parameters!"); return false; } bool success = false; /* Free output context beforehand. */ bktrFreeContext(out); /* Initialize the desired storage type. */ switch(storage_type) { case BucketTreeStorageType_Indirect: case BucketTreeStorageType_Sparse: success = bktrInitializeIndirectStorageContext(out, nca_fs_ctx, storage_type == BucketTreeStorageType_Sparse); break; case BucketTreeStorageType_AesCtrEx: success = bktrInitializeAesCtrExStorageContext(out, nca_fs_ctx); break; default: break; } if (!success) LOG_MSG_ERROR("Failed to initialize Bucket Tree %s storage for FS section #%u in \"%s\".", bktrGetStorageTypeName(storage_type), nca_fs_ctx->section_idx, \ nca_fs_ctx->nca_ctx->content_id_str); return success; } bool bktrInitializeCompressedStorageContext(BucketTreeContext *out, BucketTreeSubStorage *substorage) { if (!out || !bktrIsValidSubStorage(substorage) || substorage->index != 0 || !substorage->nca_fs_ctx->enabled || !substorage->nca_fs_ctx->has_compression_layer || \ substorage->nca_fs_ctx->section_type >= NcaFsSectionType_Invalid || !substorage->nca_fs_ctx->nca_ctx || \ (substorage->nca_fs_ctx->nca_ctx->rights_id_available && !substorage->nca_fs_ctx->nca_ctx->titlekey_retrieved) || \ substorage->type == BucketTreeSubStorageType_AesCtrEx || substorage->type == BucketTreeSubStorageType_Compressed || substorage->type >= BucketTreeSubStorageType_Count) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Free output context beforehand. */ bktrFreeContext(out); NcaFsSectionContext *nca_fs_ctx = substorage->nca_fs_ctx; NcaBucketInfo *compressed_bucket = &(nca_fs_ctx->header.compression_info.bucket); BucketTreeTable *compressed_table = NULL; u64 node_storage_size = 0, entry_storage_size = 0; BucketTreeSubStorageReadParams params = {0}; bool dump_table = false, success = false; /* Verify bucket info. */ if (!bktrVerifyBucketInfo(compressed_bucket, BKTR_NODE_SIZE, BKTR_COMPRESSED_ENTRY_SIZE, &node_storage_size, &entry_storage_size)) { LOG_MSG_ERROR("Compressed Storage BucketInfo verification failed!"); goto end; } /* Allocate memory for the full Compressed table. */ compressed_table = calloc(1, compressed_bucket->size); if (!compressed_table) { LOG_MSG_ERROR("Unable to allocate memory for the Compressed Storage Table!"); goto end; } /* Read Compressed storage table data. */ const u64 compression_table_offset = (nca_fs_ctx->hash_region.size + compressed_bucket->offset); bktrInitializeSubStorageReadParams(¶ms, compressed_table, compression_table_offset, compressed_bucket->size, 0, 0, false, BucketTreeSubStorageType_Compressed); if (!bktrReadSubStorage(substorage, ¶ms)) { LOG_MSG_ERROR("Failed to read Compressed Storage Table data!"); goto end; } dump_table = true; /* Validate table offset node. */ u64 start_offset = 0, end_offset = 0; if (!bktrValidateTableOffsetNode(compressed_table, BKTR_NODE_SIZE, BKTR_COMPRESSED_ENTRY_SIZE, compressed_bucket->header.entry_count, &start_offset, &end_offset)) { LOG_MSG_ERROR("Compressed Storage Table Offset Node validation failed!"); goto end; } /* Update output context. */ out->nca_fs_ctx = nca_fs_ctx; out->storage_type = BucketTreeStorageType_Compressed; out->storage_table = compressed_table; out->node_size = BKTR_NODE_SIZE; out->entry_size = BKTR_COMPRESSED_ENTRY_SIZE; out->offset_count = bktrGetOffsetCount(BKTR_NODE_SIZE); out->entry_set_count = bktrGetEntrySetCount(BKTR_NODE_SIZE, BKTR_COMPRESSED_ENTRY_SIZE, compressed_bucket->header.entry_count); out->node_storage_size = node_storage_size; out->entry_storage_size = entry_storage_size; out->start_offset = start_offset; out->end_offset = end_offset; memcpy(&(out->substorages[0]), substorage, sizeof(BucketTreeSubStorage)); /* Update return value. */ success = true; end: if (!success) { LOG_DATA_DEBUG(compressed_bucket, sizeof(NcaBucketInfo), "Compressed Storage BucketInfo dump:"); if (compressed_table) { if (dump_table) LOG_DATA_DEBUG(compressed_table, compressed_bucket->size, "Compressed Storage Table dump:"); free(compressed_table); } } return success; } bool bktrSetRegularSubStorage(BucketTreeContext *ctx, NcaFsSectionContext *nca_fs_ctx) { if (!bktrIsValidContext(ctx) || !nca_fs_ctx || !nca_fs_ctx->enabled || nca_fs_ctx->section_type >= NcaFsSectionType_Invalid || \ !nca_fs_ctx->nca_ctx || (nca_fs_ctx->nca_ctx->rights_id_available && !nca_fs_ctx->nca_ctx->titlekey_retrieved) || \ ctx->storage_type == BucketTreeStorageType_Compressed || ctx->storage_type >= BucketTreeStorageType_Count || \ (ctx->storage_type == BucketTreeStorageType_Indirect && ctx->nca_fs_ctx == nca_fs_ctx) || \ ((ctx->storage_type == BucketTreeStorageType_AesCtrEx || ctx->storage_type == BucketTreeStorageType_Sparse) && ctx->nca_fs_ctx != nca_fs_ctx)) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Update the substorage. */ BucketTreeSubStorage *substorage = &(ctx->substorages[0]); memset(substorage, 0, sizeof(BucketTreeSubStorage)); substorage->index = 0; substorage->nca_fs_ctx = nca_fs_ctx; substorage->type = BucketTreeSubStorageType_Regular; substorage->bktr_ctx = NULL; return true; } bool bktrSetBucketTreeSubStorage(BucketTreeContext *parent_ctx, BucketTreeContext *child_ctx, u8 substorage_index) { if (!bktrIsValidContext(parent_ctx) || !bktrIsValidContext(child_ctx) || substorage_index >= BKTR_MAX_SUBSTORAGE_COUNT || \ parent_ctx->storage_type != BucketTreeStorageType_Indirect || child_ctx->storage_type < BucketTreeStorageType_AesCtrEx || \ child_ctx->storage_type > BucketTreeStorageType_Sparse || (child_ctx->storage_type == BucketTreeStorageType_AesCtrEx && (substorage_index != 1 || \ parent_ctx->nca_fs_ctx != child_ctx->nca_fs_ctx)) || ((child_ctx->storage_type == BucketTreeStorageType_Compressed || \ child_ctx->storage_type == BucketTreeStorageType_Sparse) && (substorage_index != 0 || parent_ctx->nca_fs_ctx == child_ctx->nca_fs_ctx))) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Update the substorage. */ BucketTreeSubStorage *substorage = &(parent_ctx->substorages[substorage_index]); memset(substorage, 0, sizeof(BucketTreeSubStorage)); substorage->index = substorage_index; substorage->nca_fs_ctx = child_ctx->nca_fs_ctx; substorage->type = (child_ctx->storage_type + 1); /* Convert to BucketTreeSubStorageType value. */ substorage->bktr_ctx = child_ctx; return true; } bool bktrReadStorage(BucketTreeContext *ctx, void *out, u64 read_size, u64 offset) { if (!bktrIsBlockWithinStorageRange(ctx, read_size, offset) || !out) { LOG_MSG_ERROR("Invalid parameters!"); return false; } BucketTreeVisitor visitor = {0}; bool success = false; /* Find storage entry. */ if (!bktrFindStorageEntry(ctx, offset, &visitor)) { LOG_MSG_ERROR("Unable to find %s storage entry for offset 0x%lX!", bktrGetStorageTypeName(ctx->storage_type), offset); goto end; } /* Process storage entry according to the storage type. */ switch(ctx->storage_type) { case BucketTreeStorageType_Indirect: case BucketTreeStorageType_Sparse: success = bktrReadIndirectStorage(&visitor, out, read_size, offset); break; case BucketTreeStorageType_AesCtrEx: success = bktrReadAesCtrExStorage(&visitor, out, read_size, offset); break; case BucketTreeStorageType_Compressed: success = bktrReadCompressedStorage(&visitor, out, read_size, offset); break; default: break; } if (!success) LOG_MSG_ERROR("Failed to read 0x%lX-byte long block at offset 0x%lX from %s storage!", read_size, offset, bktrGetStorageTypeName(ctx->storage_type)); end: return success; } bool bktrIsBlockWithinIndirectStorageRange(BucketTreeContext *ctx, u64 offset, u64 size, bool *out) { if (!bktrIsBlockWithinStorageRange(ctx, size, offset) || (ctx->storage_type != BucketTreeStorageType_Indirect && ctx->storage_type != BucketTreeStorageType_Compressed) || \ (ctx->storage_type == BucketTreeStorageType_Compressed && ctx->substorages[0].type != BucketTreeSubStorageType_Indirect) || !out) { LOG_MSG_ERROR("Invalid parameters!"); return false; } BucketTreeVisitor visitor = {0}; bool updated = false, success = false; /* Find storage entry. */ if (!bktrFindStorageEntry(ctx, offset, &visitor)) { LOG_MSG_ERROR("Unable to find %s storage entry for offset 0x%lX!", bktrGetStorageTypeName(ctx->storage_type), offset); goto end; } /* Check if we're dealing with a Compressed storage. */ if (ctx->storage_type == BucketTreeStorageType_Compressed) { BucketTreeContext *indirect_storage = ctx->substorages[0].bktr_ctx; const u64 compressed_storage_base_offset = ctx->nca_fs_ctx->hash_region.size; BucketTreeCompressedStorageEntry *start_entry = NULL, *end_entry = NULL; /* Validate start entry node. */ start_entry = end_entry = (BucketTreeCompressedStorageEntry*)visitor.entry; if (!bktrIsOffsetWithinStorageRange(ctx, (u64)start_entry->virtual_offset) || (u64)start_entry->virtual_offset > offset) { LOG_MSG_ERROR("Invalid Compressed Storage entry! (0x%lX) (#1).", start_entry->virtual_offset); goto end; } /* Loop until we reach the upper bound of the requested block or find a match. */ do { u64 cur_entry_offset = 0; /* Check if we can move any further. */ if (bktrVisitorCanMoveNext(&visitor)) { BucketTreeCompressedStorageEntry *tmp = end_entry; /* Retrieve next entry node. */ if (!bktrVisitorMoveNext(&visitor)) { LOG_MSG_ERROR("Failed to retrieve next Compressed Storage entry!"); goto end; } /* Validate next entry node. */ end_entry = (BucketTreeCompressedStorageEntry*)visitor.entry; if (!bktrIsOffsetWithinStorageRange(ctx, (u64)end_entry->virtual_offset) || (u64)end_entry->virtual_offset <= (u64)tmp->virtual_offset) { LOG_MSG_ERROR("Invalid Indirect Storage entry! (0x%lX) (#2).", (u64)end_entry->virtual_offset); goto end; } /* Update current entry offset. */ cur_entry_offset = (u64)end_entry->virtual_offset; /* Update start entry node. */ start_entry = tmp; } else { /* Update current entry offset. */ cur_entry_offset = ctx->end_offset; /* Update entry nodes. */ start_entry = end_entry; end_entry = NULL; } /* Calculate indirect block extents. */ u64 indirect_block_offset = compressed_storage_base_offset; u64 indirect_block_size = (cur_entry_offset - (u64)start_entry->virtual_offset); if ((u64)start_entry->virtual_offset <= offset) { indirect_block_offset += ((offset - (u64)start_entry->virtual_offset) + (u64)start_entry->physical_offset); indirect_block_size -= (offset - (u64)start_entry->virtual_offset); } else { indirect_block_offset += (u64)start_entry->physical_offset; } if ((offset + size) <= cur_entry_offset) { indirect_block_size -= (cur_entry_offset - (offset + size)); end_entry = NULL; /* Don't proceed any further, we have found our upper bound. */ } /* Check if the current Compressed Storage entry node points to one or more Indirect Storage entry nodes with Patch storage index. */ if (!bktrIsBlockWithinIndirectStorageRange(indirect_storage, indirect_block_offset, indirect_block_size, &updated)) { LOG_MSG_ERROR("Failed to determine if 0x%lX-byte long Compressed storage block at offset 0x%lX is within Indirect Storage!", indirect_block_offset, indirect_block_size); goto end; } } while(!updated && end_entry && (u64)end_entry->virtual_offset < (offset + size)); /* Update output values. */ *out = updated; success = true; goto end; } /* Check the Indirect Storage. */ BucketTreeIndirectStorageEntry *start_entry = NULL, *end_entry = NULL; /* Validate start entry node. */ start_entry = end_entry = (BucketTreeIndirectStorageEntry*)visitor.entry; if (!bktrIsOffsetWithinStorageRange(ctx, start_entry->virtual_offset) || start_entry->virtual_offset > offset) { LOG_MSG_ERROR("Invalid Indirect Storage entry! (0x%lX) (#1).", start_entry->virtual_offset); goto end; } /* Loop through adjacent Indirect Storage entry nodes and check if at least one of them uses the Patch storage index. */ do { /* Break out of the loop immediately if the current entry node's storage index matches Patch. */ if (end_entry->storage_index == BucketTreeIndirectStorageIndex_Patch) { updated = true; break; } /* Don't proceed if we can't move any further. */ if (!bktrVisitorCanMoveNext(&visitor)) break; /* Retrieve the next entry node. */ if (!bktrVisitorMoveNext(&visitor)) { LOG_MSG_ERROR("Failed to retrieve next Indirect Storage entry!"); goto end; } /* Validate current entry node. */ end_entry = (BucketTreeIndirectStorageEntry*)visitor.entry; if (!bktrIsOffsetWithinStorageRange(ctx, end_entry->virtual_offset) || end_entry->virtual_offset <= start_entry->virtual_offset) { LOG_MSG_ERROR("Invalid Indirect Storage entry! (0x%lX) (#2).", end_entry->virtual_offset); goto end; } } while(end_entry->virtual_offset < (offset + size)); /* Update output values. */ *out = updated; success = true; end: return success; } #if LOG_LEVEL <= LOG_LEVEL_ERROR static const char *bktrGetStorageTypeName(u8 storage_type) { return (storage_type < BucketTreeStorageType_Count ? g_bktrStorageTypeNames[storage_type] : NULL); } #endif static bool bktrInitializeIndirectStorageContext(BucketTreeContext *out, NcaFsSectionContext *nca_fs_ctx, bool is_sparse) { if ((!is_sparse && nca_fs_ctx->section_type != NcaFsSectionType_PatchRomFs) || (is_sparse && !nca_fs_ctx->has_sparse_layer)) { LOG_MSG_ERROR("Invalid parameters!"); return false; } NcaContext *nca_ctx = nca_fs_ctx->nca_ctx; NcaBucketInfo *indirect_bucket = (is_sparse ? &(nca_fs_ctx->header.sparse_info.bucket) : &(nca_fs_ctx->header.patch_info.indirect_bucket)); BucketTreeTable *indirect_table = NULL; u64 node_storage_size = 0, entry_storage_size = 0; bool dump_table = false, success = false; /* Verify bucket info. */ if (!bktrVerifyBucketInfo(indirect_bucket, BKTR_NODE_SIZE, BKTR_INDIRECT_ENTRY_SIZE, &node_storage_size, &entry_storage_size)) { LOG_MSG_ERROR("Indirect Storage BucketInfo verification failed! (%s).", is_sparse ? "sparse" : "patch"); goto end; } /* Allocate memory for the full indirect table. */ indirect_table = calloc(1, indirect_bucket->size); if (!indirect_table) { LOG_MSG_ERROR("Unable to allocate memory for the Indirect Storage Table! (%s).", is_sparse ? "sparse" : "patch"); goto end; } /* Read indirect storage table data. */ if ((!is_sparse && !ncaReadFsSection(nca_fs_ctx, indirect_table, indirect_bucket->size, indirect_bucket->offset)) || \ (is_sparse && !ncaReadContentFile(nca_ctx, indirect_table, indirect_bucket->size, nca_fs_ctx->sparse_table_offset))) { LOG_MSG_ERROR("Failed to read Indirect Storage Table data! (%s).", is_sparse ? "sparse" : "patch"); goto end; } /* Decrypt indirect storage table, if needed. */ if (is_sparse) { NcaAesCtrUpperIv sparse_upper_iv = {0}; u8 sparse_ctr[AES_BLOCK_SIZE] = {0}; const u8 *sparse_ctr_key = NULL; Aes128CtrContext sparse_ctr_ctx = {0}; /* Generate upper CTR IV. */ memcpy(sparse_upper_iv.value, nca_fs_ctx->header.aes_ctr_upper_iv.value, sizeof(sparse_upper_iv.value)); sparse_upper_iv.generation = ((u32)(nca_fs_ctx->header.sparse_info.generation) << 16); /* Initialize partial AES CTR. */ aes128CtrInitializePartialCtr(sparse_ctr, sparse_upper_iv.value, nca_fs_ctx->sparse_table_offset); /* Create AES CTR context. */ sparse_ctr_key = (nca_ctx->rights_id_available ? nca_ctx->titlekey : nca_ctx->decrypted_key_area.aes_ctr); aes128CtrContextCreate(&sparse_ctr_ctx, sparse_ctr_key, sparse_ctr); /* Decrypt indirect storage table in-place. */ aes128CtrCrypt(&sparse_ctr_ctx, indirect_table, indirect_table, indirect_bucket->size); } dump_table = true; /* Validate table offset node. */ u64 start_offset = 0, end_offset = 0; if (!bktrValidateTableOffsetNode(indirect_table, BKTR_NODE_SIZE, BKTR_INDIRECT_ENTRY_SIZE, indirect_bucket->header.entry_count, &start_offset, &end_offset)) { LOG_MSG_ERROR("Indirect Storage Table Offset Node validation failed! (%s).", is_sparse ? "sparse" : "patch"); goto end; } /* Update output context. */ out->nca_fs_ctx = nca_fs_ctx; out->storage_type = (is_sparse ? BucketTreeStorageType_Sparse : BucketTreeStorageType_Indirect); out->storage_table = indirect_table; out->node_size = BKTR_NODE_SIZE; out->entry_size = BKTR_INDIRECT_ENTRY_SIZE; out->offset_count = bktrGetOffsetCount(BKTR_NODE_SIZE); out->entry_set_count = bktrGetEntrySetCount(BKTR_NODE_SIZE, BKTR_INDIRECT_ENTRY_SIZE, indirect_bucket->header.entry_count); out->node_storage_size = node_storage_size; out->entry_storage_size = entry_storage_size; out->start_offset = start_offset; out->end_offset = end_offset; /* Update return value. */ success = true; end: if (!success) { LOG_DATA_DEBUG(indirect_bucket, sizeof(NcaBucketInfo), "Indirect Storage BucketInfo dump (%s):", is_sparse ? "sparse" : "patch"); if (indirect_table) { if (dump_table) LOG_DATA_DEBUG(indirect_table, indirect_bucket->size, "Indirect Storage Table dump (%s):", is_sparse ? "sparse" : "patch"); free(indirect_table); } } return success; } static bool bktrGetIndirectStorageEntryExtents(BucketTreeVisitor *visitor, u64 offset, BucketTreeIndirectStorageEntry *out_cur_entry, u64 *out_next_entry_offset) { if (!visitor || !out_cur_entry || !out_next_entry_offset) { LOG_MSG_ERROR("Invalid parameters!"); return false; } BucketTreeContext *ctx = visitor->bktr_ctx; BucketTreeIndirectStorageEntry cur_entry = {0}; u64 cur_entry_offset = 0, next_entry_offset = 0; bool success = false; /* Copy current Indirect Storage entry -- we'll move onto the next one, so we'll lose track of it. */ memcpy(&cur_entry, visitor->entry, sizeof(BucketTreeIndirectStorageEntry)); /* Validate Indirect Storage entry. */ if (!bktrIsOffsetWithinStorageRange(ctx, cur_entry.virtual_offset) || cur_entry.virtual_offset > offset || cur_entry.storage_index > BucketTreeIndirectStorageIndex_Patch) { LOG_MSG_ERROR("Invalid Indirect Storage entry! (0x%lX) (#1).", cur_entry.virtual_offset); goto end; } cur_entry_offset = cur_entry.virtual_offset; /* Check if we can retrieve the next entry. */ if (bktrVisitorCanMoveNext(visitor)) { /* Retrieve the next entry. */ if (!bktrVisitorMoveNext(visitor)) { LOG_MSG_ERROR("Failed to retrieve next Indirect Storage entry!"); goto end; } /* Validate Indirect Storage entry. */ BucketTreeIndirectStorageEntry *next_entry = (BucketTreeIndirectStorageEntry*)visitor->entry; if (!bktrIsOffsetWithinStorageRange(ctx, next_entry->virtual_offset) || next_entry->storage_index > BucketTreeIndirectStorageIndex_Patch) { LOG_MSG_ERROR("Invalid Indirect Storage entry! (0x%lX) (#2).", next_entry->virtual_offset); goto end; } /* Store next entry's virtual offset. */ next_entry_offset = next_entry->virtual_offset; } else { /* Set the next entry offset to the storage's end. */ next_entry_offset = ctx->end_offset; } /* Verify next entry offset. */ if (next_entry_offset <= cur_entry_offset || offset >= next_entry_offset) { LOG_MSG_ERROR("Invalid virtual offset for the Indirect Storage's next entry! (0x%lX).", next_entry_offset); goto end; } /* Update variables. */ memcpy(out_cur_entry, &cur_entry, sizeof(BucketTreeIndirectStorageEntry)); *out_next_entry_offset = next_entry_offset; success = true; end: return success; } static bool bktrReadIndirectStorage(BucketTreeVisitor *visitor, void *out, u64 read_size, u64 offset) { BucketTreeContext *ctx = visitor->bktr_ctx; bool is_sparse = (ctx->storage_type == BucketTreeStorageType_Sparse); bool missing_original_storage = !bktrIsValidSubStorage(&(ctx->substorages[0])); BucketTreeIndirectStorageEntry cur_entry = {0}; BucketTreeSubStorageReadParams params = {0}; u64 cur_entry_offset = 0, next_entry_offset = 0, accum = 0; bool success = false; if (!out || (is_sparse && (missing_original_storage || ctx->substorages[0].type != BucketTreeSubStorageType_Regular)) || \ (!is_sparse && (!bktrIsValidSubStorage(&(ctx->substorages[1])) || ctx->substorages[1].type != BucketTreeSubStorageType_AesCtrEx || \ (!missing_original_storage && (ctx->substorages[0].type == BucketTreeSubStorageType_Indirect || ctx->substorages[0].type == BucketTreeSubStorageType_AesCtrEx || \ ctx->substorages[0].type >= BucketTreeSubStorageType_Count)))) || (offset + read_size) > ctx->end_offset) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Perform Indirect Storage reads until we reach the requested size. */ while(accum < read_size) { u8 *out_ptr = ((u8*)out + accum); const u64 indirect_block_offset = (offset + accum); u64 indirect_block_size = 0, indirect_block_read_size = 0, indirect_block_read_offset = 0, read_size_diff = 0; /* Get current Indirect Storage entry and the start offset for the next one. */ if (!bktrGetIndirectStorageEntryExtents(visitor, indirect_block_offset, &cur_entry, &next_entry_offset)) { LOG_MSG_ERROR("Failed to get Indirect Storage entry extents for offset 0x%lX!", indirect_block_offset); goto end; } /* Calculate Indirect Storage block size. */ cur_entry_offset = cur_entry.virtual_offset; indirect_block_size = (!accum ? (next_entry_offset - offset) : (next_entry_offset - cur_entry_offset)); /* Calculate Indirect Storage block read size and offset. */ read_size_diff = (read_size - accum); indirect_block_read_size = (read_size_diff > indirect_block_size ? indirect_block_size : read_size_diff); indirect_block_read_offset = (indirect_block_offset - cur_entry_offset + cur_entry.physical_offset); /* Perform read operation within the current Indirect Storage entry. */ bktrInitializeSubStorageReadParams(¶ms, out_ptr, indirect_block_read_offset, indirect_block_read_size, indirect_block_offset, 0, false, ctx->storage_type); if (cur_entry.storage_index == BucketTreeIndirectStorageIndex_Original) { if (!missing_original_storage) { /* Retrieve data from the original data storage. */ /* This must either be a Regular/Sparse/Compressed storage from the base NCA (Indirect) or a Regular storage from this very same NCA (Sparse). */ if (!bktrReadSubStorage(&(ctx->substorages[0]), ¶ms)) { LOG_MSG_ERROR("Failed to read 0x%lX-byte long chunk from offset 0x%lX in original data storage!", indirect_block_read_size, indirect_block_read_offset); goto end; } } else { LOG_MSG_ERROR("Error: attempting to read 0x%lX-byte long chunk from missing original data storage at offset 0x%lX!", indirect_block_read_size, indirect_block_read_offset); goto end; } } else { if (!is_sparse) { /* Retrieve data from the Indirect data storage. */ /* This must always be the AesCtrEx storage within this very same NCA (Indirect). */ if (!bktrReadSubStorage(&(ctx->substorages[1]), ¶ms)) { LOG_MSG_ERROR("Failed to read 0x%lX-byte long chunk from offset 0x%lX in AesCtrEx storage!", indirect_block_read_size, indirect_block_read_offset); goto end; } } else { /* Fill output buffer with zeroes (SparseStorage's ZeroStorage). */ memset(out_ptr, 0, indirect_block_read_size); } } /* Update accumulator. */ accum += indirect_block_read_size; } /* Update flag. */ success = true; end: return success; } static bool bktrInitializeAesCtrExStorageContext(BucketTreeContext *out, NcaFsSectionContext *nca_fs_ctx) { if (nca_fs_ctx->section_type != NcaFsSectionType_PatchRomFs || !nca_fs_ctx->header.patch_info.aes_ctr_ex_bucket.size) { LOG_MSG_ERROR("Invalid parameters!"); return false; } NcaBucketInfo *aes_ctr_ex_bucket = &(nca_fs_ctx->header.patch_info.aes_ctr_ex_bucket); BucketTreeTable *aes_ctr_ex_table = NULL; u64 node_storage_size = 0, entry_storage_size = 0; bool dump_table = false, success = false; /* Verify bucket info. */ if (!bktrVerifyBucketInfo(aes_ctr_ex_bucket, BKTR_NODE_SIZE, BKTR_AES_CTR_EX_ENTRY_SIZE, &node_storage_size, &entry_storage_size)) { LOG_MSG_ERROR("AesCtrEx Storage BucketInfo verification failed!"); goto end; } /* Allocate memory for the full AesCtrEx table. */ aes_ctr_ex_table = calloc(1, aes_ctr_ex_bucket->size); if (!aes_ctr_ex_table) { LOG_MSG_ERROR("Unable to allocate memory for the AesCtrEx Storage Table!"); goto end; } /* Read AesCtrEx storage table data. */ if (!ncaReadFsSection(nca_fs_ctx, aes_ctr_ex_table, aes_ctr_ex_bucket->size, aes_ctr_ex_bucket->offset)) { LOG_MSG_ERROR("Failed to read AesCtrEx Storage Table data!"); goto end; } dump_table = true; /* Validate table offset node. */ u64 start_offset = 0, end_offset = 0; if (!bktrValidateTableOffsetNode(aes_ctr_ex_table, BKTR_NODE_SIZE, BKTR_AES_CTR_EX_ENTRY_SIZE, aes_ctr_ex_bucket->header.entry_count, &start_offset, &end_offset)) { LOG_MSG_ERROR("AesCtrEx Storage Table Offset Node validation failed!"); goto end; } /* Update output context. */ out->nca_fs_ctx = nca_fs_ctx; out->storage_type = BucketTreeStorageType_AesCtrEx; out->storage_table = aes_ctr_ex_table; out->node_size = BKTR_NODE_SIZE; out->entry_size = BKTR_AES_CTR_EX_ENTRY_SIZE; out->offset_count = bktrGetOffsetCount(BKTR_NODE_SIZE); out->entry_set_count = bktrGetEntrySetCount(BKTR_NODE_SIZE, BKTR_AES_CTR_EX_ENTRY_SIZE, aes_ctr_ex_bucket->header.entry_count); out->node_storage_size = node_storage_size; out->entry_storage_size = entry_storage_size; out->start_offset = start_offset; out->end_offset = end_offset; /* Update return value. */ success = true; end: if (!success) { LOG_DATA_DEBUG(aes_ctr_ex_bucket, sizeof(NcaBucketInfo), "AesCtrEx Storage BucketInfo dump:"); if (aes_ctr_ex_table) { if (dump_table) LOG_DATA_DEBUG(aes_ctr_ex_table, aes_ctr_ex_bucket->size, "AesCtrEx Storage Table dump:"); free(aes_ctr_ex_table); } } return success; } static bool bktrGetAesCtrExStorageEntryExtents(BucketTreeVisitor *visitor, u64 offset, BucketTreeAesCtrExStorageEntry *out_cur_entry, u64 *out_next_entry_offset) { if (!visitor || !out_cur_entry || !out_next_entry_offset) { LOG_MSG_ERROR("Invalid parameters!"); return false; } BucketTreeContext *ctx = visitor->bktr_ctx; BucketTreeAesCtrExStorageEntry cur_entry = {0}; u64 cur_entry_offset = 0, next_entry_offset = 0; bool success = false; /* Copy current AesCtrEx Storage entry -- we'll move onto the next one, so we'll lose track of it. */ memcpy(&cur_entry, visitor->entry, sizeof(BucketTreeAesCtrExStorageEntry)); /* Validate AesCtrEx Storage entry. */ if (!bktrIsOffsetWithinStorageRange(ctx, cur_entry.offset) || cur_entry.offset > offset || !IS_ALIGNED(cur_entry.offset, AES_BLOCK_SIZE)) { LOG_MSG_ERROR("Invalid AesCtrEx Storage entry! (0x%lX) (#1).", cur_entry.offset); goto end; } cur_entry_offset = cur_entry.offset; /* Check if we can retrieve the next entry. */ if (bktrVisitorCanMoveNext(visitor)) { /* Retrieve the next entry. */ if (!bktrVisitorMoveNext(visitor)) { LOG_MSG_ERROR("Failed to retrieve next AesCtrEx Storage entry!"); goto end; } /* Validate AesCtrEx Storage entry. */ BucketTreeAesCtrExStorageEntry *next_entry = (BucketTreeAesCtrExStorageEntry*)visitor->entry; if (!bktrIsOffsetWithinStorageRange(ctx, next_entry->offset)) { LOG_MSG_ERROR("Invalid AesCtrEx Storage entry! (0x%lX) (#2).", next_entry->offset); goto end; } /* Store next entry's virtual offset. */ next_entry_offset = next_entry->offset; } else { /* Set the next entry offset to the storage's end. */ next_entry_offset = ctx->end_offset; } /* Verify next entry offset. */ if (!IS_ALIGNED(next_entry_offset, AES_BLOCK_SIZE) || next_entry_offset <= cur_entry_offset || offset >= next_entry_offset) { LOG_MSG_ERROR("Invalid offset for the AesCtrEx Storage's next entry! (0x%lX).", next_entry_offset); goto end; } /* Update variables. */ memcpy(out_cur_entry, &cur_entry, sizeof(BucketTreeAesCtrExStorageEntry)); *out_next_entry_offset = next_entry_offset; success = true; end: return success; } static bool bktrReadAesCtrExStorage(BucketTreeVisitor *visitor, void *out, u64 read_size, u64 offset) { BucketTreeContext *ctx = visitor->bktr_ctx; BucketTreeAesCtrExStorageEntry cur_entry = {0}; BucketTreeSubStorageReadParams params = {0}; u64 cur_entry_offset = 0, next_entry_offset = 0, accum = 0; bool success = false; if (!out || !bktrIsValidSubStorage(&(ctx->substorages[0])) || ctx->substorages[0].type != BucketTreeSubStorageType_Regular || (offset + read_size) > ctx->end_offset) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Perform AesCtrEx Storage reads until we reach the requested size. */ while(accum < read_size) { u8 *out_ptr = ((u8*)out + accum); const u64 aes_ctr_ex_block_offset = (offset + accum); u64 aes_ctr_ex_block_size = 0, aes_ctr_ex_block_read_size = 0, read_size_diff = 0; /* Get current AesCtrEx Storage entry and the start offset for the next one. */ if (!bktrGetAesCtrExStorageEntryExtents(visitor, aes_ctr_ex_block_offset, &cur_entry, &next_entry_offset)) { LOG_MSG_ERROR("Failed to get AesCtrEx Storage entry extents for offset 0x%lX!", aes_ctr_ex_block_offset); goto end; } /* Calculate AesCtrEx Storage block size. */ cur_entry_offset = cur_entry.offset; aes_ctr_ex_block_size = (!accum ? (next_entry_offset - offset) : (next_entry_offset - cur_entry_offset)); /* Calculate AesCtrEx Storage block read size and offset. */ read_size_diff = (read_size - accum); aes_ctr_ex_block_read_size = (read_size_diff > aes_ctr_ex_block_size ? aes_ctr_ex_block_size : read_size_diff); /* Perform read operation within the current AesCtrEx Storage entry. */ bool aes_ctr_ex_crypt = (cur_entry.encryption == BucketTreeAesCtrExStorageEncryption_Enabled); bktrInitializeSubStorageReadParams(¶ms, out_ptr, aes_ctr_ex_block_offset, aes_ctr_ex_block_read_size, 0, cur_entry.generation, aes_ctr_ex_crypt, ctx->storage_type); if (!bktrReadSubStorage(&(ctx->substorages[0]), ¶ms)) { LOG_MSG_ERROR("Failed to read 0x%lX-byte long chunk at offset 0x%lX from AesCtrEx storage!", aes_ctr_ex_block_read_size, aes_ctr_ex_block_offset); goto end; } /* Update accumulator. */ accum += aes_ctr_ex_block_read_size; } /* Update flag. */ success = true; end: return success; } static bool bktrGetCompressedStorageEntryExtents(BucketTreeVisitor *visitor, u64 offset, BucketTreeCompressedStorageEntry *out_cur_entry, u64 *out_next_entry_offset) { if (!visitor || !out_cur_entry || !out_next_entry_offset) { LOG_MSG_ERROR("Invalid parameters!"); return false; } BucketTreeContext *ctx = visitor->bktr_ctx; BucketTreeCompressedStorageEntry cur_entry = {0}; u64 cur_entry_offset = 0, next_entry_offset = 0; bool success = false; /* Copy current Compressed Storage entry -- we'll move onto the next one, so we'll lose track of it. */ memcpy(&cur_entry, visitor->entry, sizeof(BucketTreeCompressedStorageEntry)); /* Validate Compressed Storage entry. */ if (!bktrIsOffsetWithinStorageRange(ctx, (u64)cur_entry.virtual_offset) || (u64)cur_entry.virtual_offset > offset || cur_entry.compression_type == BucketTreeCompressedStorageCompressionType_2 || \ cur_entry.compression_type > BucketTreeCompressedStorageCompressionType_LZ4 || (cur_entry.compression_type != BucketTreeCompressedStorageCompressionType_LZ4 && \ cur_entry.compression_level != 0) || (cur_entry.compression_type == BucketTreeCompressedStorageCompressionType_None && cur_entry.physical_size != BKTR_COMPRESSION_INVALID_PHYS_SIZE) || \ (cur_entry.compression_type != BucketTreeCompressedStorageCompressionType_None && cur_entry.physical_size == BKTR_COMPRESSION_INVALID_PHYS_SIZE) || \ (cur_entry.compression_type == BucketTreeCompressedStorageCompressionType_LZ4 && (cur_entry.compression_level < BKTR_COMPRESSION_LEVEL_MIN || \ cur_entry.compression_level > BKTR_COMPRESSION_LEVEL_MAX || !IS_ALIGNED(cur_entry.physical_offset, BKTR_COMPRESSION_PHYS_ALIGNMENT)))) { LOG_DATA_ERROR(&cur_entry, sizeof(BucketTreeCompressedStorageEntry), "Invalid Compressed Storage entry! (#1). Entry dump:"); goto end; } cur_entry_offset = (u64)cur_entry.virtual_offset; /* Check if we can retrieve the next entry. */ if (bktrVisitorCanMoveNext(visitor)) { /* Retrieve the next entry. */ if (!bktrVisitorMoveNext(visitor)) { LOG_MSG_ERROR("Failed to retrieve next Compressed Storage entry!"); goto end; } /* Validate Compressed Storage entry. */ BucketTreeCompressedStorageEntry *next_entry = (BucketTreeCompressedStorageEntry*)visitor->entry; if (!bktrIsOffsetWithinStorageRange(ctx, (u64)next_entry->virtual_offset) || next_entry->compression_type == BucketTreeCompressedStorageCompressionType_2 || \ next_entry->compression_type > BucketTreeCompressedStorageCompressionType_LZ4 || \ (next_entry->compression_type != BucketTreeCompressedStorageCompressionType_LZ4 && next_entry->compression_level != 0) || \ (next_entry->compression_type == BucketTreeCompressedStorageCompressionType_None && next_entry->physical_size != BKTR_COMPRESSION_INVALID_PHYS_SIZE) || \ (next_entry->compression_type != BucketTreeCompressedStorageCompressionType_None && next_entry->physical_size == BKTR_COMPRESSION_INVALID_PHYS_SIZE) || \ (next_entry->compression_type == BucketTreeCompressedStorageCompressionType_LZ4 && (next_entry->compression_level < BKTR_COMPRESSION_LEVEL_MIN || \ next_entry->compression_level > BKTR_COMPRESSION_LEVEL_MAX || !IS_ALIGNED(next_entry->physical_offset, BKTR_COMPRESSION_PHYS_ALIGNMENT)))) { LOG_DATA_ERROR(next_entry, sizeof(BucketTreeCompressedStorageEntry), "Invalid Compressed Storage entry! (#2). Entry dump:"); goto end; } /* Store next entry's virtual offset. */ next_entry_offset = (u64)next_entry->virtual_offset; } else { /* Set the next entry offset to the storage's end. */ next_entry_offset = ctx->end_offset; } /* Verify next entry offset. */ if (next_entry_offset <= cur_entry_offset || offset >= next_entry_offset) { LOG_MSG_ERROR("Invalid virtual offset for the Compressed Storage's next entry! (0x%lX).", next_entry_offset); goto end; } /* Update variables. */ memcpy(out_cur_entry, &cur_entry, sizeof(BucketTreeCompressedStorageEntry)); *out_next_entry_offset = next_entry_offset; success = true; end: return success; } static bool bktrReadCompressedStorage(BucketTreeVisitor *visitor, void *out, u64 read_size, u64 offset) { BucketTreeContext *ctx = visitor->bktr_ctx; NcaFsSectionContext *nca_fs_ctx = ctx->nca_fs_ctx; u64 compressed_storage_base_offset = nca_fs_ctx->hash_region.size; BucketTreeCompressedStorageEntry cur_entry = {0}; BucketTreeSubStorageReadParams params = {0}; u64 cur_entry_offset = 0, next_entry_offset = 0, accum = 0; bool success = false; if (!out || !bktrIsValidSubStorage(&(ctx->substorages[0])) || ctx->substorages[0].type == BucketTreeSubStorageType_AesCtrEx || \ ctx->substorages[0].type == BucketTreeSubStorageType_Compressed || ctx->substorages[0].type >= BucketTreeSubStorageType_Count || (offset + read_size) > ctx->end_offset) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Perform Compressed Storage reads until we reach the requested size. */ while(accum < read_size) { u8 *out_ptr = ((u8*)out + accum); const u64 compressed_block_offset = (offset + accum); u64 compressed_block_size = 0, compressed_block_read_size = 0, compressed_block_read_offset = 0, read_size_diff = 0; /* Get current Compressed Storage entry and the start offset for the next one. */ if (!bktrGetCompressedStorageEntryExtents(visitor, compressed_block_offset, &cur_entry, &next_entry_offset)) { LOG_MSG_ERROR("Failed to get Compressed Storage entry extents for offset 0x%lX!", compressed_block_offset); goto end; } /* Calculate Compressed Storage block size. */ cur_entry_offset = cur_entry.virtual_offset; compressed_block_size = (!accum ? (next_entry_offset - offset) : (next_entry_offset - cur_entry_offset)); /* Calculate Compressed Storage block read size. */ read_size_diff = (read_size - accum); compressed_block_read_size = (read_size_diff > compressed_block_size ? compressed_block_size : read_size_diff); /* Perform read operation within the current Compressed Storage entry. */ switch(cur_entry.compression_type) { case BucketTreeCompressedStorageCompressionType_None: { /* We can randomly access data that's not compressed. */ /* Let's just read what we need. */ compressed_block_read_offset = (compressed_storage_base_offset + (compressed_block_offset - cur_entry_offset + (u64)cur_entry.physical_offset)); bktrInitializeSubStorageReadParams(¶ms, out_ptr, compressed_block_read_offset, compressed_block_read_size, 0, 0, false, ctx->storage_type); if (!bktrReadSubStorage(&(ctx->substorages[0]), ¶ms)) { LOG_MSG_ERROR("Failed to read 0x%lX-byte long chunk from offset 0x%lX in non-compressed entry!", compressed_block_read_size, compressed_block_read_offset); goto end; } break; } case BucketTreeCompressedStorageCompressionType_Zero: { /* Fill output buffer with zeroes. */ memset(out_ptr, 0, compressed_block_read_size); break; } case BucketTreeCompressedStorageCompressionType_LZ4: { /* We can't randomly access data that's compressed. */ /* Let's be lazy and allocate memory for the full entry, read it and then decompress it. */ compressed_block_read_offset = (compressed_storage_base_offset + (u64)cur_entry.physical_offset); const u64 compressed_data_size = (u64)cur_entry.physical_size; const u64 decompressed_data_size = (next_entry_offset - cur_entry_offset); const u64 buffer_size = LZ4_DECOMPRESS_INPLACE_BUFFER_SIZE(decompressed_data_size); u8 *buffer = NULL, *read_ptr = NULL; buffer = calloc(1, buffer_size); if (!buffer) { LOG_MSG_ERROR("Failed to allocate 0x%lX-byte long buffer for data decompression! (0x%lX).", buffer_size, decompressed_data_size); goto end; } /* Adjust read pointer. This will let us use the same buffer for storing read data and decompressing it. */ read_ptr = (buffer + (buffer_size - compressed_data_size)); bktrInitializeSubStorageReadParams(¶ms, read_ptr, compressed_block_read_offset, compressed_data_size, 0, 0, false, ctx->storage_type); /* Read compressed LZ4 block. */ if (!bktrReadSubStorage(&(ctx->substorages[0]), ¶ms)) { LOG_MSG_ERROR("Failed to read 0x%lX-byte long compressed block from offset 0x%lX!", compressed_data_size, compressed_block_read_offset); free(buffer); goto end; } /* Decompress LZ4 block. */ int lz4_res = LZ4_decompress_safe((char*)read_ptr, (char*)buffer, (int)compressed_data_size, (int)buffer_size); if (lz4_res != (int)decompressed_data_size) { LOG_MSG_ERROR("Failed to decompress 0x%lX-byte long compressed block! (%d).", compressed_data_size, lz4_res); free(buffer); goto end; } /* Copy the data we need. */ memcpy(out_ptr, buffer + (compressed_block_offset - cur_entry_offset), compressed_block_read_size); /* Free allocated buffer. */ free(buffer); break; } default: break; } /* Update accumulator. */ accum += compressed_block_read_size; } /* Update flag. */ success = true; end: return success; } static bool bktrReadSubStorage(BucketTreeSubStorage *substorage, BucketTreeSubStorageReadParams *params) { if (!bktrIsValidSubStorage(substorage) || !params || !params->buffer || !params->size) { LOG_MSG_ERROR("Invalid parameters!"); return false; } bool success = false; if (substorage->type == BucketTreeSubStorageType_Regular) { NcaFsSectionContext *nca_fs_ctx = substorage->nca_fs_ctx; if (params->parent_storage_type == BucketTreeStorageType_AesCtrEx) { /* Perform a read on the target NCA using AesCtrEx crypto. */ success = ncaReadAesCtrExStorage(nca_fs_ctx, params->buffer, params->size, params->offset, params->ctr_val, params->aes_ctr_ex_crypt); } else { /* Make sure to handle Sparse virtual offsets if we need to. */ if (params->parent_storage_type == BucketTreeStorageType_Sparse && params->virtual_offset) nca_fs_ctx->cur_sparse_virtual_offset = params->virtual_offset; /* Perform a read on the target NCA. */ success = ncaReadFsSection(nca_fs_ctx, params->buffer, params->size, params->offset); } } else { /* Perform a read on the target BucketTree storage. */ success = bktrReadStorage(substorage->bktr_ctx, params->buffer, params->size, params->offset); } if (!success) LOG_MSG_ERROR("Failed to read 0x%lX-byte long chunk from offset 0x%lX!", params->size, params->offset); return success; } NX_INLINE void bktrInitializeSubStorageReadParams(BucketTreeSubStorageReadParams *out, void *buffer, u64 offset, u64 size, u64 virtual_offset, u32 ctr_val, bool aes_ctr_ex_crypt, u8 parent_storage_type) { out->buffer = buffer; out->offset = offset; out->size = size; out->virtual_offset = ((virtual_offset && parent_storage_type == BucketTreeStorageType_Sparse) ? virtual_offset : 0); out->ctr_val = ((ctr_val && parent_storage_type == BucketTreeStorageType_AesCtrEx) ? ctr_val : 0); out->aes_ctr_ex_crypt = ((aes_ctr_ex_crypt && parent_storage_type == BucketTreeStorageType_AesCtrEx) ? true : false); out->parent_storage_type = parent_storage_type; } static bool bktrVerifyBucketInfo(NcaBucketInfo *bucket, u64 node_size, u64 entry_size, u64 *out_node_storage_size, u64 *out_entry_storage_size) { /* Verify bucket info properties. */ if (!ncaVerifyBucketInfo(bucket)) return false; /* Validate table size. */ u64 node_storage_size = bktrQueryNodeStorageSize(node_size, entry_size, bucket->header.entry_count); u64 entry_storage_size = bktrQueryEntryStorageSize(node_size, entry_size, bucket->header.entry_count); u64 calc_table_size = (node_storage_size + entry_storage_size); bool success = (bucket->size >= calc_table_size); if (success) { if (out_node_storage_size) *out_node_storage_size = node_storage_size; if (out_entry_storage_size) *out_entry_storage_size = entry_storage_size; } else { LOG_MSG_ERROR("Calculated table size exceeds the provided bucket's table size! (0x%lX > 0x%lX).", calc_table_size, bucket->size); } return success; } static bool bktrValidateTableOffsetNode(const BucketTreeTable *table, u64 node_size, u64 entry_size, u32 entry_count, u64 *out_start_offset, u64 *out_end_offset) { const BucketTreeOffsetNode *offset_node = &(table->offset_node); const BucketTreeNodeHeader *node_header = &(offset_node->header); /* Verify offset node header. */ if (!bktrVerifyNodeHeader(node_header, 0, node_size, sizeof(u64))) { LOG_MSG_ERROR("Bucket Tree Offset Node header verification failed!"); return false; } /* Validate offsets. */ u32 offset_count = bktrGetOffsetCount(node_size); u32 entry_set_count = bktrGetEntrySetCount(node_size, entry_size, entry_count); const u64 start_offset = ((offset_count < entry_set_count && node_header->count < offset_count) ? *bktrGetOffsetNodeEnd(offset_node) : *bktrGetOffsetNodeBegin(offset_node)); u64 end_offset = node_header->offset; if (start_offset > *bktrGetOffsetNodeBegin(offset_node) || start_offset >= end_offset || node_header->count != entry_set_count) { LOG_MSG_ERROR("Invalid Bucket Tree Offset Node!"); return false; } /* Update output offsets. */ if (out_start_offset) *out_start_offset = start_offset; if (out_end_offset) *out_end_offset = end_offset; return true; } NX_INLINE bool bktrVerifyNodeHeader(const BucketTreeNodeHeader *node_header, u32 node_index, u64 node_size, u64 entry_size) { return (node_header && node_header->index == node_index && entry_size > 0 && node_size >= (entry_size + BKTR_NODE_HEADER_SIZE) && \ node_header->count > 0 && node_header->count <= ((node_size - BKTR_NODE_HEADER_SIZE) / entry_size)); } static u64 bktrQueryNodeStorageSize(u64 node_size, u64 entry_size, u32 entry_count) { if (entry_size < sizeof(u64) || node_size < (entry_size + BKTR_NODE_HEADER_SIZE) || node_size < BKTR_NODE_SIZE_MIN || node_size > BKTR_NODE_SIZE_MAX || \ !IS_POWER_OF_TWO(node_size) || !entry_count) return 0; return ((1 + bktrGetNodeL2Count(node_size, entry_size, entry_count)) * node_size); } static u64 bktrQueryEntryStorageSize(u64 node_size, u64 entry_size, u32 entry_count) { if (entry_size < sizeof(u64) || node_size < (entry_size + BKTR_NODE_HEADER_SIZE) || node_size < BKTR_NODE_SIZE_MIN || node_size > BKTR_NODE_SIZE_MAX || \ !IS_POWER_OF_TWO(node_size) || !entry_count) return 0; return ((u64)bktrGetEntrySetCount(node_size, entry_size, entry_count) * node_size); } NX_INLINE u32 bktrGetEntryCount(u64 node_size, u64 entry_size) { return (u32)((node_size - BKTR_NODE_HEADER_SIZE) / entry_size); } NX_INLINE u32 bktrGetOffsetCount(u64 node_size) { return (u32)((node_size - BKTR_NODE_HEADER_SIZE) / sizeof(u64)); } NX_INLINE u32 bktrGetEntrySetCount(u64 node_size, u64 entry_size, u32 entry_count) { u32 entry_count_per_node = bktrGetEntryCount(node_size, entry_size); return DIVIDE_UP(entry_count, entry_count_per_node); } NX_INLINE u32 bktrGetNodeL2Count(u64 node_size, u64 entry_size, u32 entry_count) { u32 offset_count_per_node = bktrGetOffsetCount(node_size); u32 entry_set_count = bktrGetEntrySetCount(node_size, entry_size, entry_count); if (entry_set_count <= offset_count_per_node) return 0; u32 node_l2_count = DIVIDE_UP(entry_set_count, offset_count_per_node); if (node_l2_count > offset_count_per_node) return 0; return DIVIDE_UP(entry_set_count - (offset_count_per_node - (node_l2_count - 1)), offset_count_per_node); } NX_INLINE const void *bktrGetNodeArray(const BucketTreeNodeHeader *node_header) { return ((const u8*)node_header + BKTR_NODE_HEADER_SIZE); } NX_INLINE const u64 *bktrGetOffsetNodeArray(const BucketTreeOffsetNode *offset_node) { return (const u64*)bktrGetNodeArray(&(offset_node->header)); } NX_INLINE const u64 *bktrGetOffsetNodeBegin(const BucketTreeOffsetNode *offset_node) { return bktrGetOffsetNodeArray(offset_node); } NX_INLINE const u64 *bktrGetOffsetNodeEnd(const BucketTreeOffsetNode *offset_node) { return (bktrGetOffsetNodeArray(offset_node) + offset_node->header.count); } static bool bktrFindStorageEntry(BucketTreeContext *ctx, u64 virtual_offset, BucketTreeVisitor *out_visitor) { if (!ctx || virtual_offset >= ctx->storage_table->offset_node.header.offset || !out_visitor) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Get the node. */ const BucketTreeOffsetNode *offset_node = &(ctx->storage_table->offset_node); /* Get the entry node index. */ u32 entry_set_index = 0; const u64 *start_ptr = NULL, *end_ptr = NULL; bool success = false; if (bktrIsExistOffsetL2OnL1(ctx) && virtual_offset < *bktrGetOffsetNodeBegin(offset_node)) { start_ptr = bktrGetOffsetNodeEnd(offset_node); end_ptr = (bktrGetOffsetNodeBegin(offset_node) + ctx->offset_count); if (!bktrGetTreeNodeEntryIndex(start_ptr, end_ptr, virtual_offset, &entry_set_index)) { LOG_MSG_ERROR("Failed to retrieve Bucket Tree Node entry index for virtual offset 0x%lX! (#1).", virtual_offset); goto end; } } else { start_ptr = bktrGetOffsetNodeBegin(offset_node); end_ptr = bktrGetOffsetNodeEnd(offset_node); if (!bktrGetTreeNodeEntryIndex(start_ptr, end_ptr, virtual_offset, &entry_set_index)) { LOG_MSG_ERROR("Failed to retrieve Bucket Tree Node entry index for virtual offset 0x%lX! (#2).", virtual_offset); goto end; } if (bktrIsExistL2(ctx)) { u32 node_index = entry_set_index; if (node_index >= ctx->offset_count || !bktrFindEntrySet(ctx, &entry_set_index, virtual_offset, node_index)) { LOG_MSG_ERROR("Invalid L2 Bucket Tree Node index!"); goto end; } } } /* Validate the entry set index. */ if (entry_set_index >= ctx->entry_set_count) { LOG_MSG_ERROR("Invalid Bucket Tree Node offset!"); goto end; } /* Find the entry. */ success = bktrFindEntry(ctx, out_visitor, virtual_offset, entry_set_index); if (!success) LOG_MSG_ERROR("Failed to retrieve storage entry!"); end: return success; } static bool bktrGetTreeNodeEntryIndex(const u64 *start_ptr, const u64 *end_ptr, u64 virtual_offset, u32 *out_index) { if (!start_ptr || !end_ptr || start_ptr >= end_ptr || !out_index) { LOG_MSG_ERROR("Invalid parameters!"); return false; } u64 *pos = (u64*)start_ptr; u32 index = 0; while(pos < end_ptr) { if (start_ptr < pos) { /* Stop looking if we have found the right offset node. */ if (*pos > virtual_offset) break; /* Increment index. */ index++; } /* Increment offset node pointer. */ pos++; } /* Update output index. */ *out_index = index; return true; } static bool bktrGetEntryNodeEntryIndex(const BucketTreeNodeHeader *node_header, u64 entry_size, u64 virtual_offset, u32 *out_index) { if (!node_header || !out_index) { LOG_MSG_ERROR("Invalid parameters!"); return false; } /* Initialize storage node and find the index for our virtual offset. */ BucketTreeStorageNode storage_node = {0}; bktrInitializeStorageNode(&storage_node, entry_size, node_header->count); bktrStorageNodeFind(&storage_node, node_header, virtual_offset); /* Validate index. */ if (storage_node.index == UINT32_MAX) { LOG_MSG_ERROR("Unable to find index for virtual offset 0x%lX!", virtual_offset); return false; } /* Update output index. */ *out_index = storage_node.index; return true; } static bool bktrFindEntrySet(BucketTreeContext *ctx, u32 *out_index, u64 virtual_offset, u32 node_index) { /* Get offset node header. */ const BucketTreeNodeHeader *node_header = bktrGetTreeNodeHeader(ctx, node_index); if (!node_header) { LOG_MSG_ERROR("Failed to retrieve offset node header at index 0x%X!", node_index); return false; } /* Get offset node entry index. */ u32 offset_index = 0; if (!bktrGetEntryNodeEntryIndex(node_header, sizeof(u64), virtual_offset, &offset_index)) { LOG_MSG_ERROR("Failed to get offset node entry index!"); return false; } /* Update output index. */ *out_index = bktrGetEntrySetIndex(ctx, node_header->index, offset_index); return true; } static const BucketTreeNodeHeader *bktrGetTreeNodeHeader(BucketTreeContext *ctx, u32 node_index) { /* Calculate offset node extents. */ const u64 node_size = ctx->node_size; const u64 node_offset = ((node_index + 1) * node_size); if ((node_offset + BKTR_NODE_HEADER_SIZE) > ctx->node_storage_size) { LOG_MSG_ERROR("Invalid Bucket Tree Offset Node offset!"); return NULL; } /* Get offset node header. */ const BucketTreeNodeHeader *node_header = (const BucketTreeNodeHeader*)((u8*)ctx->storage_table + node_offset); /* Validate offset node header. */ if (!bktrVerifyNodeHeader(node_header, node_index, node_size, sizeof(u64))) { LOG_MSG_ERROR("Bucket Tree Offset Node header verification failed!"); return NULL; } return node_header; } NX_INLINE u32 bktrGetEntrySetIndex(BucketTreeContext *ctx, u32 node_index, u32 offset_index) { return (u32)((ctx->offset_count - ctx->storage_table->offset_node.header.count) + (ctx->offset_count * node_index) + offset_index); } static bool bktrFindEntry(BucketTreeContext *ctx, BucketTreeVisitor *out_visitor, u64 virtual_offset, u32 entry_set_index) { /* Get entry node header. */ const BucketTreeNodeHeader *entry_set_header = bktrGetEntryNodeHeader(ctx, entry_set_index); if (!entry_set_header) { LOG_MSG_ERROR("Failed to retrieve entry node header at index 0x%X!", entry_set_index); return false; } /* Calculate entry node extents. */ const u64 entry_size = ctx->entry_size; const u64 entry_set_size = ctx->node_size; const u64 entry_set_offset = (ctx->node_storage_size + (entry_set_index * entry_set_size)); /* Get entry node entry index. */ u32 entry_index = 0; if (!bktrGetEntryNodeEntryIndex(entry_set_header, entry_size, virtual_offset, &entry_index)) { LOG_MSG_ERROR("Failed to get entry node entry index!"); return false; } /* Get entry node entry offset and validate it. */ u64 entry_offset = bktrGetEntryNodeEntryOffset(entry_set_offset, entry_size, entry_index); if ((entry_offset + entry_size) > (ctx->node_storage_size + ctx->entry_storage_size)) { LOG_MSG_ERROR("Invalid Bucket Tree Entry Node entry offset!"); return false; } /* Update output visitor. */ memset(out_visitor, 0, sizeof(BucketTreeVisitor)); out_visitor->bktr_ctx = ctx; memcpy(&(out_visitor->entry_set), entry_set_header, sizeof(BucketTreeEntrySetHeader)); out_visitor->entry_index = entry_index; out_visitor->entry = ((u8*)ctx->storage_table + entry_offset); return true; } static const BucketTreeNodeHeader *bktrGetEntryNodeHeader(BucketTreeContext *ctx, u32 entry_set_index) { /* Calculate entry node extents. */ const u64 entry_size = ctx->entry_size; const u64 entry_set_size = ctx->node_size; const u64 entry_set_offset = (ctx->node_storage_size + (entry_set_index * entry_set_size)); if ((entry_set_offset + BKTR_NODE_HEADER_SIZE) > (ctx->node_storage_size + ctx->entry_storage_size)) { LOG_MSG_ERROR("Invalid Bucket Tree Entry Node offset!"); return NULL; } /* Get entry node header. */ const BucketTreeNodeHeader *entry_set_header = (const BucketTreeNodeHeader*)((u8*)ctx->storage_table + entry_set_offset); /* Validate entry node header. */ if (!bktrVerifyNodeHeader(entry_set_header, entry_set_index, entry_set_size, entry_size)) { LOG_MSG_ERROR("Bucket Tree Entry Node header verification failed!"); return NULL; } return entry_set_header; } NX_INLINE u64 bktrGetEntryNodeEntryOffset(u64 entry_set_offset, u64 entry_size, u32 entry_index) { return (entry_set_offset + BKTR_NODE_HEADER_SIZE + ((u64)entry_index * entry_size)); } NX_INLINE u64 bktrGetEntryNodeEntryOffsetByIndex(u32 entry_set_index, u64 node_size, u64 entry_size, u32 entry_index) { return bktrGetEntryNodeEntryOffset((u64)entry_set_index * node_size, entry_size, entry_index); } NX_INLINE bool bktrIsExistL2(BucketTreeContext *ctx) { return (ctx->offset_count < ctx->entry_set_count); } NX_INLINE bool bktrIsExistOffsetL2OnL1(BucketTreeContext *ctx) { return (bktrIsExistL2(ctx) && ctx->storage_table->offset_node.header.count < ctx->offset_count); } static void bktrInitializeStorageNode(BucketTreeStorageNode *out, u64 entry_size, u32 entry_count) { out->start.offset = BKTR_NODE_HEADER_SIZE; out->start.stride = (u32)entry_size; out->count = entry_count; out->index = UINT32_MAX; } static void bktrStorageNodeFind(BucketTreeStorageNode *storage_node, const BucketTreeNodeHeader *node_header, u64 virtual_offset) { /* Check for edge case, short circuit. */ if (storage_node->count == 1) { storage_node->index = 0; return; } /* Perform a binary search. */ u32 entry_count = storage_node->count, low = 0, high = (entry_count - 1); BucketTreeStorageNodeOffset *start = &(storage_node->start); while(low <= high) { /* Get the offset to the middle entry within our current lookup range. */ u32 half = ((low + high) / 2); BucketTreeStorageNodeOffset mid = bktrStorageNodeOffsetAdd(start, half); /* Check middle entry's virtual offset. */ if (bktrStorageNodeOffsetGetEntryVirtualOffset(node_header, &mid) > virtual_offset) { /* Update our upper limit. */ high = (half - 1); } else { /* Check for success. */ BucketTreeStorageNodeOffset pos = bktrStorageNodeOffsetAdd(&mid, 1); if (half == (entry_count - 1) || bktrStorageNodeOffsetGetEntryVirtualOffset(node_header, &pos) > virtual_offset) { storage_node->index = half; break; } /* Update our lower limit. */ low = (half + 1); } } } NX_INLINE BucketTreeStorageNodeOffset bktrStorageNodeOffsetAdd(BucketTreeStorageNodeOffset *ofs, u64 value) { BucketTreeStorageNodeOffset out = { ofs->offset + (value * (u64)ofs->stride), ofs->stride }; return out; } NX_INLINE const u64 bktrStorageNodeOffsetGetEntryVirtualOffset(const BucketTreeNodeHeader *node_header, const BucketTreeStorageNodeOffset *ofs) { return *((const u64*)((const u8*)node_header + ofs->offset)); } NX_INLINE bool bktrVisitorIsValid(BucketTreeVisitor *visitor) { return (visitor && visitor->bktr_ctx && visitor->entry_index != UINT32_MAX); } NX_INLINE bool bktrVisitorCanMoveNext(BucketTreeVisitor *visitor) { return (bktrVisitorIsValid(visitor) && ((visitor->entry_index + 1) < visitor->entry_set.header.count || (visitor->entry_set.header.index + 1) < visitor->bktr_ctx->entry_set_count)); } static bool bktrVisitorMoveNext(BucketTreeVisitor *visitor) { if (!bktrVisitorIsValid(visitor)) { LOG_MSG_ERROR("Invalid parameters!"); return false; } BucketTreeContext *ctx = visitor->bktr_ctx; BucketTreeEntrySetHeader *entry_set = &(visitor->entry_set); u32 entry_index = (visitor->entry_index + 1); bool success = false; /* Invalidate index. */ visitor->entry_index = UINT32_MAX; if (entry_index == entry_set->header.count) { /* We have reached the end of this entry node. Let's try to retrieve the first entry from the next one. */ const u32 entry_set_index = (entry_set->header.index + 1); if (entry_set_index >= ctx->entry_set_count) { LOG_MSG_ERROR("Error: attempting to move visitor into non-existing Bucket Tree Entry Node!"); goto end; } /* Read next entry set header. */ const u64 end_offset = entry_set->header.offset; const u64 entry_set_size = ctx->node_size; const u64 entry_set_offset = (ctx->node_storage_size + (entry_set_index * entry_set_size)); if ((entry_set_offset + sizeof(BucketTreeEntrySetHeader)) > (ctx->node_storage_size + ctx->entry_storage_size)) { LOG_MSG_ERROR("Invalid Bucket Tree Entry Node offset!"); goto end; } memcpy(entry_set, (u8*)ctx->storage_table + entry_set_offset, sizeof(BucketTreeEntrySetHeader)); /* Validate next entry set header. */ if (!bktrVerifyNodeHeader(&(entry_set->header), entry_set_index, entry_set_size, ctx->entry_size) || entry_set->start != end_offset || \ entry_set->start >= entry_set->header.offset) { LOG_MSG_ERROR("Bucket Tree Entry Node header verification failed!"); goto end; } /* Update entry index. */ entry_index = 0; } /* Get the new entry. */ const u64 entry_size = ctx->entry_size; const u64 entry_offset = (ctx->node_storage_size + bktrGetEntryNodeEntryOffsetByIndex(entry_set->header.index, ctx->node_size, entry_size, entry_index)); if ((entry_offset + entry_size) > (ctx->node_storage_size + ctx->entry_storage_size)) { LOG_MSG_ERROR("Invalid Bucket Tree Entry Node entry offset!"); goto end; } /* Update visitor. */ visitor->entry_index = entry_index; visitor->entry = ((u8*)ctx->storage_table + entry_offset); /* Update return value. */ success = true; end: return success; }