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nxdumptool/include/core/pfs.h
Pablo Curiel d402776032 Custom devoptab wrappers (part 1).
This commit implements a devoptab wrapper for Partition FS sections within NCAs, using code from pfs.c/h.

Other changes include:

* codebase: use NX_IGNORE_ARG macro where needed.

* hfs: slight tweaks to some of the static functions.

* pfs: slight tweaks to some of the static functions.
* pfs: use pfsIsValidContext() where needed.

* utils: update utilsInitializeResources() to use __system_argc and __system_argv variables from libnx.

* todo: update text file.
2023-12-20 20:32:48 +01:00

204 lines
8.5 KiB
C

/*
* pfs.h
*
* Copyright (c) 2020-2023, 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 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 <https://www.gnu.org/licenses/>.
*/
#pragma once
#ifndef __PFS_H__
#define __PFS_H__
#include "nca_storage.h"
#ifdef __cplusplus
extern "C" {
#endif
#define PFS0_MAGIC 0x50465330 /* "PFS0". */
typedef struct {
u32 magic; ///< "PFS0".
u32 entry_count;
u32 name_table_size;
u8 reserved[0x4];
} PartitionFileSystemHeader;
NXDT_ASSERT(PartitionFileSystemHeader, 0x10);
typedef struct {
u64 offset;
u64 size;
u32 name_offset;
u8 reserved[0x4];
} PartitionFileSystemEntry;
NXDT_ASSERT(PartitionFileSystemEntry, 0x18);
/// Used with Partition FS sections from NCAs.
typedef struct {
NcaStorageContext storage_ctx; ///< Used to read NCA FS section data.
NcaFsSectionContext *nca_fs_ctx; ///< Same as storage_ctx.nca_fs_ctx. Placed here for convenience.
u64 offset; ///< Partition offset (relative to the start of the NCA FS section).
u64 size; ///< Partition size.
bool is_exefs; ///< ExeFS flag.
u64 header_size; ///< Full header size.
u8 *header; ///< PartitionFileSystemHeader + (PartitionFileSystemEntry * entry_count) + Name Table.
} PartitionFileSystemContext;
/// Used to generate Partition FS images (e.g. NSPs).
typedef struct {
PartitionFileSystemHeader header; ///< Partition FS header. Holds the entry count and name table size.
PartitionFileSystemEntry *entries; ///< Partition FS entries.
char *name_table; ///< Name table.
u64 fs_size; ///< Partition FS data size. Updated each time a new entry is added.
} PartitionFileSystemImageContext;
/// Initializes a Partition FS context.
bool pfsInitializeContext(PartitionFileSystemContext *out, NcaFsSectionContext *nca_fs_ctx);
/// Reads raw partition data using a Partition FS context.
/// Input offset must be relative to the start of the Partition FS.
bool pfsReadPartitionData(PartitionFileSystemContext *ctx, void *out, u64 read_size, u64 offset);
/// Reads data from a previously retrieved PartitionFileSystemEntry using a Partition FS context.
/// Input offset must be relative to the start of the Partition FS entry.
bool pfsReadEntryData(PartitionFileSystemContext *ctx, PartitionFileSystemEntry *fs_entry, void *out, u64 read_size, u64 offset);
/// Retrieves a Partition FS entry index by its name.
bool pfsGetEntryIndexByName(PartitionFileSystemContext *ctx, const char *name, u32 *out_idx);
/// Calculates the extracted Partition FS size.
bool pfsGetTotalDataSize(PartitionFileSystemContext *ctx, u64 *out_size);
/// Generates HierarchicalSha256 FS section patch data using a Partition FS context + entry, which can be used to seamlessly replace NCA data.
/// Input offset must be relative to the start of the Partition FS entry data.
/// This function shares the same limitations as ncaGenerateHierarchicalSha256Patch().
/// Use the pfsWriteEntryPatchToMemoryBuffer() wrapper to write patch data generated by this function.
bool pfsGenerateEntryPatch(PartitionFileSystemContext *ctx, PartitionFileSystemEntry *fs_entry, const void *data, u64 data_size, u64 data_offset, NcaHierarchicalSha256Patch *out);
/// Adds a new Partition FS entry to an existing PartitionFileSystemImageContext, using the provided entry name and size.
/// If 'out_entry_idx' is a valid pointer, the index to the new Partition FS entry will be saved to it.
bool pfsAddEntryInformationToImageContext(PartitionFileSystemImageContext *ctx, const char *entry_name, u64 entry_size, u32 *out_entry_idx);
/// Updates the name from a Partition FS entry in an existing PartitionFileSystemImageContext, using an entry index and the new entry name.
bool pfsUpdateEntryNameFromImageContext(PartitionFileSystemImageContext *ctx, u32 entry_idx, const char *new_entry_name);
/// Generates a full Partition FS header from an existing PartitionFileSystemImageContext and writes it to the provided memory buffer.
bool pfsWriteImageContextHeaderToMemoryBuffer(PartitionFileSystemImageContext *ctx, void *buf, u64 buf_size, u64 *out_header_size);
/// Miscellaneous functions.
NX_INLINE void pfsFreeContext(PartitionFileSystemContext *ctx)
{
if (!ctx) return;
ncaStorageFreeContext(&(ctx->storage_ctx));
if (ctx->header) free(ctx->header);
memset(ctx, 0, sizeof(PartitionFileSystemContext));
}
/// Checks if the provided PartitionFileSystemContext is valid.
NX_INLINE bool pfsIsValidContext(PartitionFileSystemContext *ctx)
{
return (ctx && ncaStorageIsValidContext(&(ctx->storage_ctx)) && ctx->nca_fs_ctx == ctx->storage_ctx.nca_fs_ctx && \
ctx->storage_ctx.base_storage_type == NcaStorageBaseStorageType_Regular && ctx->size && ctx->header_size && ctx->header);
}
NX_INLINE u32 pfsGetEntryCount(PartitionFileSystemContext *ctx)
{
return (pfsIsValidContext(ctx) ? ((PartitionFileSystemHeader*)ctx->header)->entry_count : 0);
}
NX_INLINE PartitionFileSystemEntry *pfsGetEntryByIndex(PartitionFileSystemContext *ctx, u32 idx)
{
return (idx < pfsGetEntryCount(ctx) ? (PartitionFileSystemEntry*)(ctx->header + sizeof(PartitionFileSystemHeader) + (idx * sizeof(PartitionFileSystemEntry))) : NULL);
}
NX_INLINE char *pfsGetNameTable(PartitionFileSystemContext *ctx)
{
u32 entry_count = pfsGetEntryCount(ctx);
return (entry_count ? (char*)(ctx->header + sizeof(PartitionFileSystemHeader) + (entry_count * sizeof(PartitionFileSystemEntry))) : NULL);
}
NX_INLINE char *pfsGetEntryName(PartitionFileSystemContext *ctx, PartitionFileSystemEntry *fs_entry)
{
char *name_table = pfsGetNameTable(ctx);
if (!name_table || !fs_entry || fs_entry->name_offset >= ((PartitionFileSystemHeader*)ctx->header)->name_table_size || !name_table[fs_entry->name_offset]) return NULL;
return (name_table + fs_entry->name_offset);
}
NX_INLINE char *pfsGetEntryNameByIndex(PartitionFileSystemContext *ctx, u32 idx)
{
PartitionFileSystemEntry *fs_entry = pfsGetEntryByIndex(ctx, idx);
char *name_table = pfsGetNameTable(ctx);
return ((fs_entry && name_table) ? (name_table + fs_entry->name_offset) : NULL);
}
NX_INLINE PartitionFileSystemEntry *pfsGetEntryByName(PartitionFileSystemContext *ctx, const char *name)
{
u32 idx = 0;
return (pfsGetEntryIndexByName(ctx, name, &idx) ? pfsGetEntryByIndex(ctx, idx) : NULL);
}
NX_INLINE void pfsWriteEntryPatchToMemoryBuffer(PartitionFileSystemContext *ctx, NcaHierarchicalSha256Patch *patch, void *buf, u64 buf_size, u64 buf_offset)
{
if (!pfsIsValidContext(ctx)) return;
ncaWriteHierarchicalSha256PatchToMemoryBuffer(ctx->nca_fs_ctx->nca_ctx, patch, buf, buf_size, buf_offset);
}
NX_INLINE void pfsFreeEntryPatch(NcaHierarchicalSha256Patch *patch)
{
ncaFreeHierarchicalSha256Patch(patch);
}
NX_INLINE void pfsFreeImageContext(PartitionFileSystemImageContext *ctx)
{
if (!ctx) return;
if (ctx->entries) free(ctx->entries);
if (ctx->name_table) free(ctx->name_table);
memset(ctx, 0, sizeof(PartitionFileSystemImageContext));
}
NX_INLINE void pfsInitializeImageContext(PartitionFileSystemImageContext *ctx)
{
if (!ctx) return;
pfsFreeImageContext(ctx);
ctx->header.magic = __builtin_bswap32(PFS0_MAGIC);
}
NX_INLINE u32 pfsGetEntryCountFromImageContext(PartitionFileSystemImageContext *ctx)
{
return (ctx ? ctx->header.entry_count : 0);
}
NX_INLINE PartitionFileSystemEntry *pfsGetEntryByIndexFromImageContext(PartitionFileSystemImageContext *ctx, u32 idx)
{
return (idx < pfsGetEntryCountFromImageContext(ctx) ? &(ctx->entries[idx]) : NULL);
}
NX_INLINE char *pfsGetEntryNameByIndexFromImageContext(PartitionFileSystemImageContext *ctx, u32 idx)
{
PartitionFileSystemEntry *fs_entry = pfsGetEntryByIndexFromImageContext(ctx, idx);
return ((fs_entry && ctx->name_table) ? (ctx->name_table + fs_entry->name_offset) : NULL);
}
#ifdef __cplusplus
}
#endif
#endif /* __PFS_H__ */