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nxdumptool/source/save.c
2020-04-18 23:03:58 -04:00

2015 lines
72 KiB
C

#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <errno.h>
#include "save.h"
#include "util.h"
#include "keys.h"
#define REMAP_ENTRY_LENGTH 0x20
/* Extern variables */
extern nca_keyset_t nca_keyset;
extern char strbuf[NAME_BUF_LEN];
/* Statically allocated variables */
static bool loadedCerts = false, personalizedCertAvailable = false;
static const char *cert_CA00000003_path = "/certificate/CA00000003";
static const char *cert_XS00000020_path = "/certificate/XS00000020";
static const char *cert_XS00000021_path = "/certificate/XS00000021";
static const char *cert_XS00000024_path = "/certificate/XS00000024"; // 9.0.0+
static const u8 cert_CA00000003_hash[0x20] = {
0x62, 0x69, 0x0E, 0xC0, 0x4C, 0x62, 0x9D, 0x08, 0x38, 0xBB, 0xDF, 0x65, 0xC5, 0xA6, 0xB0, 0x9A,
0x54, 0x94, 0x2C, 0x87, 0x0E, 0x01, 0x55, 0x73, 0xCF, 0x7D, 0x58, 0xF2, 0x59, 0xFE, 0x36, 0xFA
};
static const u8 cert_XS00000020_hash[0x20] = {
0x55, 0x23, 0x17, 0xD4, 0x4B, 0xAF, 0x4C, 0xF5, 0x31, 0x8E, 0xF5, 0xC6, 0x4E, 0x0F, 0x75, 0xD9,
0x75, 0xD4, 0x03, 0xFD, 0x7B, 0x93, 0x7B, 0xAB, 0x46, 0x7D, 0x37, 0x94, 0x62, 0x39, 0x33, 0xE9
};
static const u8 cert_XS00000021_hash[0x20] = {
0xDE, 0xFF, 0x96, 0x01, 0x42, 0x1E, 0x00, 0xC1, 0x52, 0x60, 0x5C, 0x9F, 0x42, 0xCD, 0x91, 0xD7,
0x90, 0x01, 0xC5, 0x7F, 0xC3, 0x27, 0x58, 0x4B, 0xD9, 0x6F, 0x71, 0x78, 0xC9, 0x44, 0xD0, 0xAD
};
static const u8 cert_XS00000024_hash[0x20] = {
0xB7, 0x32, 0x8D, 0x69, 0xB9, 0xA7, 0xE4, 0x1C, 0x9C, 0xF9, 0xD8, 0x6B, 0x79, 0x81, 0x07, 0x9B,
0x20, 0x02, 0x12, 0xF6, 0xB9, 0x41, 0x33, 0x2C, 0x61, 0x57, 0x1E, 0x3A, 0x62, 0x53, 0x7C, 0x89
};
static u8 cert_root_data[ETICKET_CA_CERT_SIZE];
static u8 cert_common_data[ETICKET_XS_CERT_SIZE];
static u8 cert_personalized_data[ETICKET_XS_CERT_SIZE];
static const u8 personalized_cert_count = 2;
static inline void save_bitmap_set_bit(void *buffer, size_t bit_offset)
{
*((u8*)buffer + (bit_offset >> 3)) |= 1 << (bit_offset & 7);
}
static inline void save_bitmap_clear_bit(void *buffer, size_t bit_offset)
{
*((u8*)buffer + (bit_offset >> 3)) &= ~(u8)(1 << (bit_offset & 7));
}
static inline u8 save_bitmap_check_bit(const void *buffer, size_t bit_offset)
{
return (*((u8*)buffer + (bit_offset >> 3)) & (1 << (bit_offset & 7)));
}
bool save_duplex_storage_init(duplex_storage_ctx_t *ctx, duplex_fs_layer_info_t *layer, void *bitmap, u64 bitmap_size)
{
if (!ctx || !layer || !layer->data_a || !layer->data_b || !layer->info.block_size_power || !bitmap || !bitmap_size)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to initialize duplex storage!", __func__);
return false;
}
ctx->data_a = layer->data_a;
ctx->data_b = layer->data_b;
ctx->bitmap_storage = (u8*)bitmap;
ctx->block_size = (1 << layer->info.block_size_power);
ctx->bitmap.data = ctx->bitmap_storage;
ctx->bitmap.bitmap = calloc(1, bitmap_size >> 3);
if (!ctx->bitmap.bitmap)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for duplex bitmap!", __func__);
return false;
}
u32 bits_remaining = bitmap_size;
u32 bitmap_pos = 0;
u32 *buffer_pos = (u32*)bitmap;
while(bits_remaining)
{
u32 bits_to_read = (bits_remaining < 32 ? bits_remaining : 32);
u32 val = *buffer_pos;
for(u32 i = 0; i < bits_to_read; i++)
{
if (val & 0x80000000)
{
save_bitmap_set_bit(ctx->bitmap.bitmap, bitmap_pos);
} else {
save_bitmap_clear_bit(ctx->bitmap.bitmap, bitmap_pos);
}
bitmap_pos++;
bits_remaining--;
val <<= 1;
}
buffer_pos++;
}
return true;
}
u32 save_duplex_storage_read(duplex_storage_ctx_t *ctx, void *buffer, u64 offset, size_t count)
{
if (!ctx || !ctx->block_size || !ctx->bitmap.bitmap || !buffer || !count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read duplex storage data!", __func__);
return 0;
}
u64 in_pos = offset;
u32 out_pos = 0;
u32 remaining = count;
while(remaining)
{
u32 block_num = (u32)(in_pos / ctx->block_size);
u32 block_pos = (u32)(in_pos % ctx->block_size);
u32 bytes_to_read = ((ctx->block_size - block_pos) < remaining ? (ctx->block_size - block_pos) : remaining);
u8 *data = (save_bitmap_check_bit(ctx->bitmap.bitmap, block_num) ? ctx->data_b : ctx->data_a);
memcpy((u8*)buffer + out_pos, data + in_pos, bytes_to_read);
out_pos += bytes_to_read;
in_pos += bytes_to_read;
remaining -= bytes_to_read;
}
return out_pos;
}
remap_segment_ctx_t *save_remap_init_segments(remap_header_t *header, remap_entry_ctx_t *map_entries, u32 num_map_entries)
{
if (!header || !header->map_segment_count || !map_entries || !num_map_entries)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to initialize remap segments!", __func__);
return NULL;
}
remap_segment_ctx_t *segments = calloc(header->map_segment_count, sizeof(remap_segment_ctx_t));
if (!segments)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate initial memory for remap segments!", __func__);
return NULL;
}
unsigned int i, entry_idx = 0;
bool success = false;
for(i = 0; i < header->map_segment_count; i++)
{
remap_segment_ctx_t *seg = &(segments[i]);
seg->entry_count = 0;
seg->entries = calloc(1, sizeof(remap_entry_ctx_t*));
if (!seg->entries)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for remap segment entry #%u!", __func__, entry_idx);
goto out;
}
seg->entries[seg->entry_count++] = &map_entries[entry_idx];
seg->offset = map_entries[entry_idx].virtual_offset;
map_entries[entry_idx++].segment = seg;
while(entry_idx < num_map_entries && map_entries[entry_idx - 1].virtual_offset_end == map_entries[entry_idx].virtual_offset)
{
map_entries[entry_idx].segment = seg;
map_entries[entry_idx - 1].next = &map_entries[entry_idx];
remap_entry_ctx_t **ptr = calloc(sizeof(remap_entry_ctx_t*), seg->entry_count + 1);
if (!ptr)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for remap segment entry #%u!", __func__, entry_idx);
goto out;
}
memcpy(ptr, seg->entries, sizeof(remap_entry_ctx_t*) * seg->entry_count);
free(seg->entries);
seg->entries = ptr;
seg->entries[seg->entry_count++] = &map_entries[entry_idx++];
}
seg->length = (seg->entries[seg->entry_count - 1]->virtual_offset_end - seg->entries[0]->virtual_offset);
}
success = true;
out:
if (!success)
{
entry_idx = 0;
for(unsigned int j = 0; j <= i; j++)
{
if (!map_entries[entry_idx].segment) break;
if (map_entries[entry_idx].segment->entries)
{
free(map_entries[entry_idx].segment->entries);
map_entries[entry_idx].segment->entries = NULL;
}
map_entries[entry_idx++].segment = NULL;
while(entry_idx < num_map_entries && map_entries[entry_idx - 1].virtual_offset_end == map_entries[entry_idx].virtual_offset)
{
map_entries[entry_idx - 1].next = NULL;
if (!map_entries[entry_idx].segment) break;
if (map_entries[entry_idx].segment->entries)
{
free(map_entries[entry_idx].segment->entries);
map_entries[entry_idx].segment->entries = NULL;
}
map_entries[entry_idx++].segment = NULL;
}
}
free(segments);
segments = NULL;
}
return segments;
}
remap_entry_ctx_t *save_remap_get_map_entry(remap_storage_ctx_t *ctx, u64 offset)
{
if (!ctx || !ctx->header || !ctx->segments)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to retrieve map entry!", __func__);
return NULL;
}
u32 segment_idx = (u32)(offset >> (64 - ctx->header->segment_bits));
if (segment_idx < ctx->header->map_segment_count)
{
for(unsigned int i = 0; i < ctx->segments[segment_idx].entry_count; i++)
{
if (ctx->segments[segment_idx].entries[i]->virtual_offset_end > offset) return ctx->segments[segment_idx].entries[i];
}
}
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: unable to find map entry for offset 0x%lX!", __func__, offset);
return NULL;
}
u32 save_remap_read(remap_storage_ctx_t *ctx, void *buffer, u64 offset, size_t count)
{
if (!ctx || (ctx->type == STORAGE_BYTES && !ctx->file) || (ctx->type == STORAGE_DUPLEX && !ctx->duplex) || (ctx->type != STORAGE_BYTES && ctx->type != STORAGE_DUPLEX) || !buffer || !count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read remap data!", __func__);
return 0;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
remap_entry_ctx_t *entry = save_remap_get_map_entry(ctx, offset);
if (!entry)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve map entry!", __func__);
strcat(strbuf, tmp);
return 0;
}
u64 in_pos = offset;
u32 out_pos = 0;
u32 remaining = count;
UINT br = 0;
FRESULT fr;
while(remaining)
{
u64 entry_pos = (in_pos - entry->virtual_offset);
u32 bytes_to_read = ((entry->virtual_offset_end - in_pos) < remaining ? (u32)(entry->virtual_offset_end - in_pos) : remaining);
switch (ctx->type)
{
case STORAGE_BYTES:
fr = f_lseek(ctx->file, ctx->base_storage_offset + entry->physical_offset + entry_pos);
if (fr || f_tell(ctx->file) != (ctx->base_storage_offset + entry->physical_offset + entry_pos))
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to seek to offset 0x%lX in savefile! (%u)", __func__, ctx->base_storage_offset + entry->physical_offset + entry_pos, fr);
return out_pos;
}
fr = f_read(ctx->file, (u8*)buffer + out_pos, bytes_to_read, &br);
if (fr || br != bytes_to_read)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read %u bytes chunk from offset 0x%lX in savefile! (%u)", __func__, bytes_to_read, ctx->base_storage_offset + entry->physical_offset + entry_pos, fr);
return (out_pos + br);
}
break;
case STORAGE_DUPLEX:
br = save_duplex_storage_read(ctx->duplex, (u8*)buffer + out_pos, ctx->base_storage_offset + entry->physical_offset + entry_pos, bytes_to_read);
if (br != bytes_to_read)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read remap data from duplex storage!", __func__);
strcat(strbuf, tmp);
return (out_pos + br);
}
break;
default:
break;
}
out_pos += bytes_to_read;
in_pos += bytes_to_read;
remaining -= bytes_to_read;
if (in_pos >= entry->virtual_offset_end) entry = entry->next;
}
return out_pos;
}
u32 save_journal_storage_read(journal_storage_ctx_t *ctx, remap_storage_ctx_t *remap, void *buffer, u64 offset, size_t count)
{
if (!ctx || !ctx->block_size || !remap || !buffer || !count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read journal storage data!", __func__);
return 0;
}
u64 in_pos = offset;
u32 out_pos = 0;
u32 remaining = count;
u32 br;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
while(remaining)
{
u32 block_num = (u32)(in_pos / ctx->block_size);
u32 block_pos = (u32)(in_pos % ctx->block_size);
u64 physical_offset = (ctx->map.entries[block_num].physical_index * ctx->block_size + block_pos);
u32 bytes_to_read = ((ctx->block_size - block_pos) < remaining ? (ctx->block_size - block_pos) : remaining);
br = save_remap_read(remap, (u8*)buffer + out_pos, ctx->journal_data_offset + physical_offset, bytes_to_read);
if (br != bytes_to_read)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: invalid parameters to read journal storage data!", __func__);
strcat(strbuf, tmp);
return (out_pos + br);
}
out_pos += bytes_to_read;
in_pos += bytes_to_read;
remaining -= bytes_to_read;
}
return out_pos;
}
bool save_ivfc_storage_init(hierarchical_integrity_verification_storage_ctx_t *ctx, u64 master_hash_offset, ivfc_save_hdr_t *ivfc)
{
if (!ctx || !ctx->levels || !ivfc || !ivfc->num_levels)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to initialize IVFC storage!", __func__);
return false;
}
bool success = false;
ivfc_level_save_ctx_t *levels = ctx->levels;
levels[0].type = STORAGE_BYTES;
levels[0].hash_offset = master_hash_offset;
for(unsigned int i = 1; i < 4; i++)
{
ivfc_level_hdr_t *level = &ivfc->level_headers[i - 1];
levels[i].type = STORAGE_REMAP;
levels[i].data_offset = level->logical_offset;
levels[i].data_size = level->hash_data_size;
}
if (ivfc->num_levels == 5)
{
ivfc_level_hdr_t *data_level = &ivfc->level_headers[ivfc->num_levels - 2];
levels[ivfc->num_levels - 1].type = STORAGE_JOURNAL;
levels[ivfc->num_levels - 1].data_offset = data_level->logical_offset;
levels[ivfc->num_levels - 1].data_size = data_level->hash_data_size;
}
struct salt_source_t {
char string[50];
u32 length;
};
static const struct salt_source_t salt_sources[6] = {
{"HierarchicalIntegrityVerificationStorage::Master", 48},
{"HierarchicalIntegrityVerificationStorage::L1", 44},
{"HierarchicalIntegrityVerificationStorage::L2", 44},
{"HierarchicalIntegrityVerificationStorage::L3", 44},
{"HierarchicalIntegrityVerificationStorage::L4", 44},
{"HierarchicalIntegrityVerificationStorage::L5", 44}
};
integrity_verification_info_ctx_t init_info[ivfc->num_levels];
init_info[0].data = &levels[0];
init_info[0].block_size = 0;
for(unsigned int i = 1; i < ivfc->num_levels; i++)
{
init_info[i].data = &levels[i];
init_info[i].block_size = (1 << ivfc->level_headers[i - 1].block_size);
hmacSha256CalculateMac(init_info[i].salt, salt_sources[i - 1].string, salt_sources[i - 1].length, ivfc->salt_source, 0x20);
}
ctx->integrity_storages[0].next_level = NULL;
ctx->level_validities = calloc(sizeof(validity_t*), (ivfc->num_levels - 1));
if (!ctx->level_validities)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for level validities!", __func__);
goto out;
}
for(unsigned int i = 1; i < ivfc->num_levels; i++)
{
integrity_verification_storage_ctx_t *level_data = &ctx->integrity_storages[i - 1];
level_data->hash_storage = &levels[i - 1];
level_data->base_storage = &levels[i];
level_data->sector_size = init_info[i].block_size;
level_data->_length = init_info[i].data->data_size;
level_data->sector_count = ((level_data->_length + level_data->sector_size - 1) / level_data->sector_size);
memcpy(level_data->salt, init_info[i].salt, 0x20);
level_data->block_validities = calloc(sizeof(validity_t), level_data->sector_count);
if (!level_data->block_validities)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for block validities in IVFC level #%u!", __func__, i);
goto out;
}
ctx->level_validities[i - 1] = level_data->block_validities;
if (i > 1) level_data->next_level = &ctx->integrity_storages[i - 2];
}
ctx->data_level = &levels[ivfc->num_levels - 1];
ctx->_length = ctx->integrity_storages[ivfc->num_levels - 2]._length;
success = true;
out:
if (!success && ctx->level_validities)
{
free(ctx->level_validities);
ctx->level_validities = NULL;
for(unsigned int i = 1; i < ivfc->num_levels; i++)
{
integrity_verification_storage_ctx_t *level_data = &ctx->integrity_storages[i - 1];
if (level_data->block_validities)
{
free(level_data->block_validities);
level_data->block_validities = NULL;
ctx->level_validities[i - 1] = NULL;
} else {
break;
}
}
}
return success;
}
size_t save_ivfc_level_fread(ivfc_level_save_ctx_t *ctx, void *buffer, u64 offset, size_t count)
{
if (!ctx || (ctx->type == STORAGE_BYTES && !ctx->save_ctx->file) || (ctx->type != STORAGE_BYTES && ctx->type != STORAGE_REMAP && ctx->type != STORAGE_JOURNAL) || !buffer || !count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read IVFC level data!", __func__);
return 0;
}
UINT br = 0;
FRESULT fr;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
switch (ctx->type)
{
case STORAGE_BYTES:
fr = f_lseek(ctx->save_ctx->file, ctx->hash_offset + offset);
if (fr || f_tell(ctx->save_ctx->file) != (ctx->hash_offset + offset))
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to seek to offset 0x%lX in savefile! (%u)", __func__, ctx->hash_offset + offset, fr);
return (size_t)br;
}
fr = f_read(ctx->save_ctx->file, buffer, count, &br);
if (fr || br != count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read IVFC level data from offset 0x%lX in savefile! (%u)", __func__, ctx->hash_offset + offset, fr);
return (size_t)br;
}
break;
case STORAGE_REMAP:
br = save_remap_read(&ctx->save_ctx->meta_remap_storage, buffer, ctx->data_offset + offset, count);
if (br != count)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read IVFC level data from remap storage!", __func__);
strcat(strbuf, tmp);
return (size_t)br;
}
break;
case STORAGE_JOURNAL:
br = save_journal_storage_read(&ctx->save_ctx->journal_storage, &ctx->save_ctx->data_remap_storage, buffer, ctx->data_offset + offset, count);
if (br != count)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read IVFC level data from journal storage!", __func__);
strcat(strbuf, tmp);
return (size_t)br;
}
break;
default:
return 0;
}
return count;
}
bool save_ivfc_storage_read(integrity_verification_storage_ctx_t *ctx, void *buffer, u64 offset, size_t count, u32 verify)
{
if (!ctx || !ctx->sector_size || (!ctx->next_level && !ctx->hash_storage && !ctx->base_storage) || !buffer || !count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read IVFC storage data!", __func__);
return false;
}
if (count > ctx->sector_size)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: IVFC read exceeds sector size!", __func__);
return false;
}
u64 block_index = (offset / ctx->sector_size);
if (ctx->block_validities[block_index] == VALIDITY_INVALID && verify)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: hash error from previous check found at offset 0x%08X, count 0x%lX!", __func__, (u32)offset, count);
return false;
}
u8 hash_buffer[0x20] = {0};
u8 zeroes[0x20] = {0};
u64 hash_pos = (block_index * 0x20);
char tmp[NAME_BUF_LEN / 2] = {'\0'};
if (ctx->next_level)
{
if (!save_ivfc_storage_read(ctx->next_level, hash_buffer, hash_pos, 0x20, verify))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read hash from next IVFC level!", __func__);
strcat(strbuf, tmp);
return false;
}
} else {
if (save_ivfc_level_fread(ctx->hash_storage, hash_buffer, hash_pos, 0x20) != 0x20)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read hash from hash storage!", __func__);
strcat(strbuf, tmp);
return false;
}
}
if (!memcmp(hash_buffer, zeroes, 0x20))
{
memset(buffer, 0, count);
ctx->block_validities[block_index] = VALIDITY_VALID;
return true;
}
if (save_ivfc_level_fread(ctx->base_storage, buffer, offset, count) != count)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read IVFC level from base storage!", __func__);
strcat(strbuf, tmp);
return false;
}
if (!(verify && ctx->block_validities[block_index] == VALIDITY_UNCHECKED)) return true;
u8 hash[0x20] = {0};
u8 *data_buffer = calloc(1, ctx->sector_size + 0x20);
if (!data_buffer)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for data buffer!", __func__);
return false;
}
memcpy(data_buffer, ctx->salt, 0x20);
memcpy(data_buffer + 0x20, buffer, ctx->sector_size);
sha256CalculateHash(hash, data_buffer, ctx->sector_size + 0x20);
hash[0x1F] |= 0x80;
free(data_buffer);
ctx->block_validities[block_index] = (!memcmp(hash_buffer, hash, 0x20) ? VALIDITY_VALID : VALIDITY_INVALID);
if (ctx->block_validities[block_index] == VALIDITY_INVALID && verify)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: hash error from current check found at offset 0x%08X, count 0x%lX!", __func__, (u32)offset, count);
return false;
}
return true;
}
u32 save_allocation_table_read_entry_with_length(allocation_table_ctx_t *ctx, allocation_table_entry_t *entry)
{
if (!ctx || !ctx->base_storage || !entry)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read entry!", __func__);
return 0;
}
u32 length = 1;
u32 entry_index = allocation_table_block_to_entry_index(entry->next);
allocation_table_entry_t *entries = (allocation_table_entry_t*)((u8*)(ctx->base_storage) + (entry_index * SAVE_FAT_ENTRY_SIZE));
if ((entries[0].next & 0x80000000) == 0)
{
if ((entries[0].prev & 0x80000000) && entries[0].prev != 0x80000000)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid range entry in allocation table!", __func__);
return 0;
}
} else {
length = (entries[1].next - entry_index + 1);
}
if (allocation_table_is_list_end(&entries[0]))
{
entry->next = 0xFFFFFFFF;
} else {
entry->next = allocation_table_entry_index_to_block(allocation_table_get_next(&entries[0]));
}
if (allocation_table_is_list_start(&entries[0]))
{
entry->prev = 0xFFFFFFFF;
} else {
entry->prev = allocation_table_entry_index_to_block(allocation_table_get_prev(&entries[0]));
}
return length;
}
u32 save_allocation_table_get_list_length(allocation_table_ctx_t *ctx, u32 block_index)
{
if (!ctx || !ctx->header->allocation_table_block_count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to calculate FAT list length!", __func__);
return 0;
}
allocation_table_entry_t entry;
entry.next = block_index;
u32 total_length = 0;
u32 table_size = ctx->header->allocation_table_block_count;
u32 nodes_iterated = 0;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
while(entry.next != 0xFFFFFFFF)
{
u32 entry_length = save_allocation_table_read_entry_with_length(ctx, &entry);
if (!entry_length)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve FAT entry length!", __func__);
strcat(strbuf, tmp);
return 0;
}
total_length += entry_length;
nodes_iterated++;
if (nodes_iterated > table_size)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: cycle detected in allocation table!", __func__);
return 0;
}
}
return total_length;
}
bool save_allocation_table_iterator_begin(allocation_table_iterator_ctx_t *ctx, allocation_table_ctx_t *table, u32 initial_block)
{
if (!ctx || !table)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to initialize FAT interator!", __func__);
return false;
}
ctx->fat = table;
ctx->physical_block = initial_block;
ctx->virtual_block = 0;
allocation_table_entry_t entry;
entry.next = initial_block;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
ctx->current_segment_size = save_allocation_table_read_entry_with_length(ctx->fat, &entry);
if (!ctx->current_segment_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve FAT entry length!", __func__);
strcat(strbuf, tmp);
return false;
}
ctx->next_block = entry.next;
ctx->prev_block = entry.prev;
if (ctx->prev_block != 0xFFFFFFFF)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: attempted to start FAT iteration from invalid block 0x%08X!", __func__, initial_block);
return false;
}
return true;
}
bool save_allocation_table_iterator_move_next(allocation_table_iterator_ctx_t *ctx)
{
if (!ctx || ctx->next_block == 0xFFFFFFFF)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to move iterator to the next block.", __func__);
return false;
}
ctx->virtual_block += ctx->current_segment_size;
ctx->physical_block = ctx->next_block;
allocation_table_entry_t entry;
entry.next = ctx->next_block;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
ctx->current_segment_size = save_allocation_table_read_entry_with_length(ctx->fat, &entry);
if (!ctx->current_segment_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve current segment size!", __func__);
strcat(strbuf, tmp);
return false;
}
ctx->next_block = entry.next;
ctx->prev_block = entry.prev;
return true;
}
bool save_allocation_table_iterator_move_prev(allocation_table_iterator_ctx_t *ctx)
{
if (!ctx || ctx->prev_block == 0xFFFFFFFF)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to move iterator to the previous block!", __func__);
return false;
}
ctx->physical_block = ctx->prev_block;
allocation_table_entry_t entry;
entry.next = ctx->prev_block;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
ctx->current_segment_size = save_allocation_table_read_entry_with_length(ctx->fat, &entry);
if (!ctx->current_segment_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve current segment size!", __func__);
strcat(strbuf, tmp);
return false;
}
ctx->next_block = entry.next;
ctx->prev_block = entry.prev;
ctx->virtual_block -= ctx->current_segment_size;
return true;
}
bool save_allocation_table_iterator_seek(allocation_table_iterator_ctx_t *ctx, u32 block)
{
while(true)
{
if (block < ctx->virtual_block)
{
if (!save_allocation_table_iterator_move_prev(ctx)) return false;
} else
if (block >= ctx->virtual_block + ctx->current_segment_size)
{
if (!save_allocation_table_iterator_move_next(ctx)) return false;
} else {
return true;
}
}
}
u32 save_allocation_table_storage_read(allocation_table_storage_ctx_t *ctx, void *buffer, u64 offset, size_t count)
{
if (!ctx || !ctx->fat || !ctx->block_size || !buffer || !count)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read data from FAT storage!", __func__);
return 0;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
allocation_table_iterator_ctx_t iterator;
if (!save_allocation_table_iterator_begin(&iterator, ctx->fat, ctx->initial_block))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to initialize FAT interator!", __func__);
strcat(strbuf, tmp);
return 0;
}
u64 in_pos = offset;
u32 out_pos = 0;
u32 remaining = count;
while(remaining)
{
u32 block_num = (u32)(in_pos / ctx->block_size);
if (!save_allocation_table_iterator_seek(&iterator, block_num))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to seek to block #%u within offset 0x%lX!", __func__, block_num, offset);
strcat(strbuf, tmp);
return out_pos;
}
u32 segment_pos = (u32)(in_pos - ((u64)iterator.virtual_block * ctx->block_size));
u64 physical_offset = ((iterator.physical_block * ctx->block_size) + segment_pos);
u32 remaining_in_segment = ((iterator.current_segment_size * ctx->block_size) - segment_pos);
u32 bytes_to_read = (remaining < remaining_in_segment ? remaining : remaining_in_segment);
u32 sector_size = ctx->base_storage->integrity_storages[3].sector_size;
u32 chunk_remaining = bytes_to_read;
for(unsigned int i = 0; i < bytes_to_read; i += sector_size)
{
u32 bytes_to_request = (chunk_remaining < sector_size ? chunk_remaining : sector_size);
if (!save_ivfc_storage_read(&ctx->base_storage->integrity_storages[3], (u8*)buffer + out_pos + i, physical_offset + i, bytes_to_request, ctx->base_storage->data_level->save_ctx->tool_ctx.action & ACTION_VERIFY))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read %u bytes chunk from IVFC storage at physical offset 0x%lX!", __func__, bytes_to_request, physical_offset + i);
strcat(strbuf, tmp);
return (out_pos + bytes_to_read - chunk_remaining);
}
chunk_remaining -= bytes_to_request;
}
out_pos += bytes_to_read;
in_pos += bytes_to_read;
remaining -= bytes_to_read;
}
return out_pos;
}
u32 save_fs_list_get_capacity(save_filesystem_list_ctx_t *ctx)
{
if (!ctx)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to retrieve FS capacity!", __func__);
return 0;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
if (!ctx->capacity)
{
if (save_allocation_table_storage_read(&ctx->storage, &ctx->capacity, 4, 4) != 4)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FS capacity from FAT storage!", __func__);
strcat(strbuf, tmp);
return 0;
}
}
return ctx->capacity;
}
u32 save_fs_list_read_entry(save_filesystem_list_ctx_t *ctx, u32 index, save_fs_list_entry_t *entry)
{
if (!ctx || !entry)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to read FS entry!", __func__);
return 0;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
u32 ret = save_allocation_table_storage_read(&ctx->storage, entry, index * SAVE_FS_LIST_ENTRY_SIZE, SAVE_FS_LIST_ENTRY_SIZE);
if (ret != SAVE_FS_LIST_ENTRY_SIZE)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FS entry from FAT storage!", __func__);
strcat(strbuf, tmp);
return 0;
}
return ret;
}
bool save_fs_list_get_value(save_filesystem_list_ctx_t *ctx, u32 index, save_fs_list_entry_t *value)
{
if (!ctx || !value)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to retrieve value for index!", __func__);
return false;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
u32 capacity = save_fs_list_get_capacity(ctx);
if (!capacity)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve FS capacity!", __func__);
strcat(strbuf, tmp);
return false;
}
if (index >= capacity)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: provided index exceeds FS capacity!", __func__);
return false;
}
if (!save_fs_list_read_entry(ctx, index, value))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FS entry!", __func__);
strcat(strbuf, tmp);
return false;
}
return true;
}
u32 save_fs_get_index_from_key(save_filesystem_list_ctx_t *ctx, save_entry_key_t *key, u32 *prev_index)
{
char tmp[NAME_BUF_LEN / 2] = {'\0'};
u32 prev;
if (!prev_index) prev_index = &prev;
if (!ctx || !key)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to retrieve FS index from key!", __func__);
goto out;
}
u32 capacity = save_fs_list_get_capacity(ctx);
if (!capacity)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve FS capacity!", __func__);
strcat(strbuf, tmp);
goto out;
}
save_fs_list_entry_t entry;
if (!save_fs_list_read_entry(ctx, ctx->used_list_head_index, &entry))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FS entry for initial index %u!", __func__, ctx->used_list_head_index);
strcat(strbuf, tmp);
goto out;
}
*prev_index = ctx->used_list_head_index;
u32 index = entry.next;
while(index)
{
if (index > capacity)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: save entry index %d out of range!", __func__, index);
break;
}
if (!save_fs_list_read_entry(ctx, index, &entry))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FS entry for index %u!", __func__, index);
strcat(strbuf, tmp);
break;
}
if (entry.parent == key->parent && !strcmp(entry.name, key->name)) return index;
*prev_index = index;
index = entry.next;
}
if (!index) snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: unable to find FS index from key!", __func__);
out:
*prev_index = 0xFFFFFFFF;
return 0xFFFFFFFF;
}
bool save_hierarchical_file_table_find_path_recursive(hierarchical_save_file_table_ctx_t *ctx, save_entry_key_t *key, const char *path)
{
if (!ctx || !key || !path || !strlen(path))
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to find FS path!", __func__);
return false;
}
key->parent = 0;
char *pos = strchr(path, '/');
while(pos)
{
memset(key->name, 0, SAVE_FS_LIST_MAX_NAME_LENGTH);
char *tmp = strchr(pos, '/');
if (!tmp)
{
memcpy(key->name, pos, strlen(pos));
break;
}
memcpy(key->name, pos, tmp - pos);
key->parent = save_fs_get_index_from_key(&ctx->directory_table, key, NULL);
if (key->parent == 0xFFFFFFFF) return false;
pos = (tmp + 1);
}
return true;
}
bool save_hierarchical_file_table_get_file_entry_by_path(hierarchical_save_file_table_ctx_t *ctx, const char *path, save_fs_list_entry_t *entry)
{
if (!ctx || !path || !strlen(path) || !entry)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to retrieve file entry!", __func__);
return false;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
save_entry_key_t key;
if (!save_hierarchical_file_table_find_path_recursive(ctx, &key, path))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: unable to locate file \"%s\".", __func__, path);
strcat(strbuf, tmp);
return false;
}
u32 index = save_fs_get_index_from_key(&ctx->file_table, &key, NULL);
if (index == 0xFFFFFFFF)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: unable to get table index for file \"%s\".", __func__, path);
strcat(strbuf, tmp);
return false;
}
if (!save_fs_list_get_value(&ctx->file_table, index, entry))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: unable to get file entry for \"%s\" from index.", __func__, path);
strcat(strbuf, tmp);
return false;
}
return true;
}
bool save_open_fat_storage(save_filesystem_ctx_t *ctx, allocation_table_storage_ctx_t *storage_ctx, u32 block_index)
{
if (!ctx || !ctx->base_storage || !storage_ctx)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to open savefile FAT storage!", __func__);
return false;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
storage_ctx->base_storage = ctx->base_storage;
storage_ctx->fat = &ctx->allocation_table;
storage_ctx->block_size = (u32)ctx->header->block_size;
storage_ctx->initial_block = block_index;
if (block_index == 0xFFFFFFFF)
{
storage_ctx->_length = 0;
} else {
u32 fat_list_length = save_allocation_table_get_list_length(storage_ctx->fat, block_index);
if (!fat_list_length)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve FAT list length!", __func__);
strcat(strbuf, tmp);
return false;
}
storage_ctx->_length = (fat_list_length * storage_ctx->block_size);
}
return true;
}
bool save_filesystem_init(save_filesystem_ctx_t *ctx, void *fat, save_fs_header_t *save_fs_header, fat_header_t *fat_header)
{
if (!ctx || !fat || !save_fs_header || !fat_header)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to initialize savefile FS!", __func__);
return false;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
ctx->allocation_table.base_storage = fat;
ctx->allocation_table.header = fat_header;
ctx->allocation_table.free_list_entry_index = 0;
ctx->header = save_fs_header;
if (!save_open_fat_storage(ctx, &ctx->file_table.directory_table.storage, fat_header->directory_table_block))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to open FAT directory storage!", __func__);
strcat(strbuf, tmp);
return false;
}
if (!save_open_fat_storage(ctx, &ctx->file_table.file_table.storage, fat_header->file_table_block))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to open FAT file storage!", __func__);
strcat(strbuf, tmp);
return false;
}
ctx->file_table.file_table.free_list_head_index = 0;
ctx->file_table.file_table.used_list_head_index = 1;
ctx->file_table.directory_table.free_list_head_index = 0;
ctx->file_table.directory_table.used_list_head_index = 1;
return true;
}
validity_t save_ivfc_validate(hierarchical_integrity_verification_storage_ctx_t *ctx, ivfc_save_hdr_t *ivfc)
{
if (!ctx || !ivfc || !ivfc->num_levels)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to verify savefile FS!", __func__);
return VALIDITY_INVALID;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
validity_t result = VALIDITY_VALID;
for(unsigned int i = 0; i < (ivfc->num_levels - 1) && result != VALIDITY_INVALID; i++)
{
integrity_verification_storage_ctx_t *storage = &ctx->integrity_storages[i];
u64 block_size = storage->sector_size;
u32 block_count = (u32)((storage->_length + block_size - 1) / block_size);
u8 *buffer = calloc(1, block_size);
if (!buffer)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for input buffer!", __func__);
result = VALIDITY_INVALID;
break;
}
for(unsigned int j = 0; j < block_count; j++)
{
if (ctx->level_validities[ivfc->num_levels - 2][j] == VALIDITY_UNCHECKED)
{
u32 to_read = ((storage->_length - (block_size * j)) < block_size ? (storage->_length - (block_size * j)) : block_size);
if (!save_ivfc_storage_read(storage, buffer, block_size * j, to_read, 1))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read IVFC storage data!", __func__);
strcat(strbuf, tmp);
result = VALIDITY_INVALID;
break;
}
}
if (ctx->level_validities[ivfc->num_levels - 2][j] == VALIDITY_INVALID)
{
result = VALIDITY_INVALID;
break;
}
}
free(buffer);
if (result == VALIDITY_INVALID) break;
}
return result;
}
bool save_ivfc_set_level_validities(hierarchical_integrity_verification_storage_ctx_t *ctx, ivfc_save_hdr_t *ivfc)
{
if (!ctx || !ivfc || !ivfc->num_levels)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to set IVFC level validities!", __func__);
return false;
}
bool success = true;
for(unsigned int i = 0; i < (ivfc->num_levels - 1); i++)
{
validity_t level_validity = VALIDITY_VALID;
for(unsigned int j = 0; j < ctx->integrity_storages[i].sector_count; j++)
{
if (ctx->level_validities[i][j] == VALIDITY_INVALID)
{
level_validity = VALIDITY_INVALID;
break;
}
if (ctx->level_validities[i][j] == VALIDITY_UNCHECKED && level_validity != VALIDITY_INVALID) level_validity = VALIDITY_UNCHECKED;
}
ctx->levels[i].hash_validity = level_validity;
if (success && level_validity == VALIDITY_INVALID) success = false;
}
if (!success) snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid IVFC level!", __func__);
return success;
}
validity_t save_filesystem_verify(save_ctx_t *ctx)
{
if (!ctx)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to verify savefile FS!", __func__);
return VALIDITY_INVALID;
}
char tmp[NAME_BUF_LEN / 2] = {'\0'};
validity_t journal_validity = save_ivfc_validate(&ctx->core_data_ivfc_storage, &ctx->header.data_ivfc_header);
if (journal_validity == VALIDITY_INVALID)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid core IVFC storage!", __func__);
return journal_validity;
}
if (!save_ivfc_set_level_validities(&ctx->core_data_ivfc_storage, &ctx->header.data_ivfc_header))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: invalid IVFC level in core IVFC storage!", __func__);
strcat(strbuf, tmp);
journal_validity = VALIDITY_INVALID;
return journal_validity;
}
if (!ctx->fat_ivfc_storage.levels[0].save_ctx) return journal_validity;
validity_t fat_validity = save_ivfc_validate(&ctx->fat_ivfc_storage, &ctx->header.fat_ivfc_header);
if (fat_validity == VALIDITY_INVALID)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid FAT IVFC storage!", __func__);
return fat_validity;
}
if (!save_ivfc_set_level_validities(&ctx->fat_ivfc_storage, &ctx->header.fat_ivfc_header))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: invalid IVFC level in FAT IVFC storage!", __func__);
strcat(strbuf, tmp);
fat_validity = VALIDITY_INVALID;
return fat_validity;
}
if (journal_validity != VALIDITY_VALID) return journal_validity;
if (fat_validity != VALIDITY_VALID) return fat_validity;
return journal_validity;
}
bool save_process(save_ctx_t *ctx)
{
strbuf[0] = '\0';
if (!ctx || !ctx->file)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to process savefile!", __func__);
return false;
}
UINT br = 0;
FRESULT fr;
bool success = false;
char tmp[NAME_BUF_LEN / 2] = {'\0'};
/* Try to parse Header A. */
f_rewind(ctx->file);
fr = f_read(ctx->file, &ctx->header, sizeof(ctx->header), &br);
if (fr || br != sizeof(ctx->header))
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read savefile header A! (%u)", __func__, fr);
return success;
}
if (!save_process_header(ctx) || ctx->header_hash_validity == VALIDITY_INVALID)
{
/* Try to parse Header B. */
fr = f_lseek(ctx->file, 0x4000);
if (fr || f_tell(ctx->file) != 0x4000)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to seek to offset 0x4000 in savefile! (%u)", __func__, fr);
return success;
}
fr = f_read(ctx->file, &ctx->header, sizeof(ctx->header), &br);
if (fr || br != sizeof(ctx->header))
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read savefile header B! (%u)", __func__, fr);
return success;
}
if (!save_process_header(ctx) || ctx->header_hash_validity == VALIDITY_INVALID)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: savefile header is invalid!", __func__);
return success;
}
}
unsigned char cmac[0x10];
memset(cmac, 0, 0x10);
cmacAes128CalculateMac(cmac, ctx->save_mac_key, &ctx->header.layout, sizeof(ctx->header.layout));
ctx->header_cmac_validity = (!memcmp(cmac, &ctx->header.cmac, 0x10) ? VALIDITY_VALID : VALIDITY_INVALID);
/* Initialize remap storages. */
ctx->data_remap_storage.type = STORAGE_BYTES;
ctx->data_remap_storage.base_storage_offset = ctx->header.layout.file_map_data_offset;
ctx->data_remap_storage.header = &ctx->header.main_remap_header;
ctx->data_remap_storage.file = ctx->file;
ctx->data_remap_storage.map_entries = calloc(sizeof(remap_entry_ctx_t), ctx->data_remap_storage.header->map_entry_count);
if (!ctx->data_remap_storage.map_entries)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for data remap storage entries!", __func__);
return success;
}
fr = f_lseek(ctx->file, ctx->header.layout.file_map_entry_offset);
if (fr || f_tell(ctx->file) != ctx->header.layout.file_map_entry_offset)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to seek to file map entry offset 0x%lX in savefile! (%u)", __func__, ctx->header.layout.file_map_entry_offset, fr);
return success;
}
for(unsigned int i = 0; i < ctx->data_remap_storage.header->map_entry_count; i++)
{
fr = f_read(ctx->file, &ctx->data_remap_storage.map_entries[i], 0x20, &br);
if (fr || br != 0x20)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read data remap storage entry #%u! (%u)", __func__, i, fr);
goto out;
}
ctx->data_remap_storage.map_entries[i].physical_offset_end = (ctx->data_remap_storage.map_entries[i].physical_offset + ctx->data_remap_storage.map_entries[i].size);
ctx->data_remap_storage.map_entries[i].virtual_offset_end = (ctx->data_remap_storage.map_entries[i].virtual_offset + ctx->data_remap_storage.map_entries[i].size);
}
/* Initialize data remap storage. */
ctx->data_remap_storage.segments = save_remap_init_segments(ctx->data_remap_storage.header, ctx->data_remap_storage.map_entries, ctx->data_remap_storage.header->map_entry_count);
if (!ctx->data_remap_storage.segments)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve data remap storage segments!", __func__);
strcat(strbuf, tmp);
goto out;
}
/* Initialize duplex storage. */
ctx->duplex_layers[0].data_a = ((u8*)&ctx->header + ctx->header.layout.duplex_master_offset_a);
ctx->duplex_layers[0].data_b = ((u8*)&ctx->header + ctx->header.layout.duplex_master_offset_b);
memcpy(&ctx->duplex_layers[0].info, &ctx->header.duplex_header.layers[0], sizeof(duplex_info_t));
ctx->duplex_layers[1].data_a = calloc(1, ctx->header.layout.duplex_l1_size);
if (!ctx->duplex_layers[1].data_a)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for data_a block in duplex layer #1!", __func__);
goto out;
}
if (save_remap_read(&ctx->data_remap_storage, ctx->duplex_layers[1].data_a, ctx->header.layout.duplex_l1_offset_a, ctx->header.layout.duplex_l1_size) != ctx->header.layout.duplex_l1_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read data_a block from duplex layer #1 in data remap storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
ctx->duplex_layers[1].data_b = calloc(1, ctx->header.layout.duplex_l1_size);
if (!ctx->duplex_layers[1].data_b)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for data_b block in duplex layer #1!", __func__);
goto out;
}
if (save_remap_read(&ctx->data_remap_storage, ctx->duplex_layers[1].data_b, ctx->header.layout.duplex_l1_offset_b, ctx->header.layout.duplex_l1_size) != ctx->header.layout.duplex_l1_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read data_b block from duplex layer #1 in data remap storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
memcpy(&ctx->duplex_layers[1].info, &ctx->header.duplex_header.layers[1], sizeof(duplex_info_t));
ctx->duplex_layers[2].data_a = calloc(1, ctx->header.layout.duplex_data_size);
if (!ctx->duplex_layers[2].data_a)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for data_a block in duplex layer #2!", __func__);
goto out;
}
if (save_remap_read(&ctx->data_remap_storage, ctx->duplex_layers[2].data_a, ctx->header.layout.duplex_data_offset_a, ctx->header.layout.duplex_data_size) != ctx->header.layout.duplex_data_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read data_a block from duplex layer #2 in data remap storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
ctx->duplex_layers[2].data_b = calloc(1, ctx->header.layout.duplex_data_size);
if (!ctx->duplex_layers[2].data_b)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for data_b block in duplex layer #2!", __func__);
goto out;
}
if (save_remap_read(&ctx->data_remap_storage, ctx->duplex_layers[2].data_b, ctx->header.layout.duplex_data_offset_b, ctx->header.layout.duplex_data_size) != ctx->header.layout.duplex_data_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read data_b block from duplex layer #2 in data remap storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
memcpy(&ctx->duplex_layers[2].info, &ctx->header.duplex_header.layers[2], sizeof(duplex_info_t));
/* Initialize hierarchical duplex storage. */
u8 *bitmap = (ctx->header.layout.duplex_index == 1 ? ctx->duplex_layers[0].data_b : ctx->duplex_layers[0].data_a);
if (!save_duplex_storage_init(&ctx->duplex_storage.layers[0], &ctx->duplex_layers[1], bitmap, ctx->header.layout.duplex_master_size))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to initialize duplex storage layer #0!", __func__);
strcat(strbuf, tmp);
goto out;
}
ctx->duplex_storage.layers[0]._length = ctx->header.layout.duplex_l1_size;
bitmap = calloc(1, ctx->duplex_storage.layers[0]._length);
if (!bitmap)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for duplex storage layer #0 bitmap!", __func__);
goto out;
}
if (save_duplex_storage_read(&ctx->duplex_storage.layers[0], bitmap, 0, ctx->duplex_storage.layers[0]._length) != ctx->duplex_storage.layers[0]._length)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read duplex storage layer #0 bitmap!", __func__);
free(bitmap);
goto out;
}
if (!save_duplex_storage_init(&ctx->duplex_storage.layers[1], &ctx->duplex_layers[2], bitmap, ctx->duplex_storage.layers[0]._length))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to initialize duplex storage layer #1!", __func__);
strcat(strbuf, tmp);
goto out;
}
ctx->duplex_storage.layers[1]._length = ctx->header.layout.duplex_data_size;
ctx->duplex_storage.data_layer = ctx->duplex_storage.layers[1];
/* Initialize meta remap storage. */
ctx->meta_remap_storage.type = STORAGE_DUPLEX;
ctx->meta_remap_storage.duplex = &ctx->duplex_storage.data_layer;
ctx->meta_remap_storage.header = &ctx->header.meta_remap_header;
ctx->meta_remap_storage.file = ctx->file;
ctx->meta_remap_storage.map_entries = calloc(sizeof(remap_entry_ctx_t), ctx->meta_remap_storage.header->map_entry_count);
if (!ctx->meta_remap_storage.map_entries)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for meta remap storage entries!", __func__);
goto out;
}
fr = f_lseek(ctx->file, ctx->header.layout.meta_map_entry_offset);
if (fr || f_tell(ctx->file) != ctx->header.layout.meta_map_entry_offset)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to seek to meta map entry offset 0x%lX in savefile! (%u)", __func__, ctx->header.layout.meta_map_entry_offset, fr);
goto out;
}
for(unsigned int i = 0; i < ctx->meta_remap_storage.header->map_entry_count; i++)
{
fr = f_read(ctx->file, &ctx->meta_remap_storage.map_entries[i], 0x20, &br);
if (fr || br != 0x20)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read meta remap storage entry #%u! (%u)", __func__, i, fr);
goto out;
}
ctx->meta_remap_storage.map_entries[i].physical_offset_end = (ctx->meta_remap_storage.map_entries[i].physical_offset + ctx->meta_remap_storage.map_entries[i].size);
ctx->meta_remap_storage.map_entries[i].virtual_offset_end = (ctx->meta_remap_storage.map_entries[i].virtual_offset + ctx->meta_remap_storage.map_entries[i].size);
}
ctx->meta_remap_storage.segments = save_remap_init_segments(ctx->meta_remap_storage.header, ctx->meta_remap_storage.map_entries, ctx->meta_remap_storage.header->map_entry_count);
if (!ctx->meta_remap_storage.segments)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to retrieve meta remap storage segments!", __func__);
strcat(strbuf, tmp);
goto out;
}
/* Initialize journal map. */
ctx->journal_map_info.map_storage = calloc(1, ctx->header.layout.journal_map_table_size);
if (!ctx->journal_map_info.map_storage)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for journal map info!", __func__);
goto out;
}
if (save_remap_read(&ctx->meta_remap_storage, ctx->journal_map_info.map_storage, ctx->header.layout.journal_map_table_offset, ctx->header.layout.journal_map_table_size) != ctx->header.layout.journal_map_table_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read map storage from journal map info in meta remap storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
/* Initialize journal storage. */
ctx->journal_storage.header = &ctx->header.journal_header;
ctx->journal_storage.journal_data_offset = ctx->header.layout.journal_data_offset;
ctx->journal_storage._length = (ctx->journal_storage.header->total_size - ctx->journal_storage.header->journal_size);
ctx->journal_storage.file = ctx->file;
ctx->journal_storage.map.header = &ctx->header.map_header;
ctx->journal_storage.map.map_storage = ctx->journal_map_info.map_storage;
ctx->journal_storage.map.entries = calloc(sizeof(journal_map_entry_t), ctx->journal_storage.map.header->main_data_block_count);
if (!ctx->journal_storage.map.entries)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for journal map storage entries!", __func__);
goto out;
}
u32 *pos = (u32*)ctx->journal_storage.map.map_storage;
for(unsigned int i = 0; i < ctx->journal_storage.map.header->main_data_block_count; i++)
{
ctx->journal_storage.map.entries[i].virtual_index = i;
ctx->journal_storage.map.entries[i].physical_index = (*pos & 0x7FFFFFFF);
pos += 2;
}
ctx->journal_storage.block_size = ctx->journal_storage.header->block_size;
ctx->journal_storage._length = (ctx->journal_storage.header->total_size - ctx->journal_storage.header->journal_size);
/* Initialize core IVFC storage. */
for(unsigned int i = 0; i < 5; i++) ctx->core_data_ivfc_storage.levels[i].save_ctx = ctx;
if (!save_ivfc_storage_init(&ctx->core_data_ivfc_storage, ctx->header.layout.ivfc_master_hash_offset_a, &ctx->header.data_ivfc_header))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to initialize core IVFC storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
/* Initialize FAT storage. */
if (ctx->header.layout.version < 0x50000)
{
ctx->fat_storage = calloc(1, ctx->header.layout.fat_size);
if (!ctx->fat_storage)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for FAT storage!", __func__);
goto out;
}
if (save_remap_read(&ctx->meta_remap_storage, ctx->fat_storage, ctx->header.layout.fat_offset, ctx->header.layout.fat_size) != ctx->header.layout.fat_size)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FAT storage from meta remap storage!", __func__);
strcat(strbuf, tmp);
goto out;
}
} else {
for(unsigned int i = 0; i < 5; i++) ctx->fat_ivfc_storage.levels[i].save_ctx = ctx;
if (!save_ivfc_storage_init(&ctx->fat_ivfc_storage, ctx->header.layout.fat_ivfc_master_hash_a, &ctx->header.fat_ivfc_header))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to initialize FAT storage (IVFC)!", __func__);
strcat(strbuf, tmp);
goto out;
}
ctx->fat_storage = calloc(1, ctx->fat_ivfc_storage._length);
if (!ctx->fat_storage)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for FAT storage (IVFC)!", __func__);
goto out;
}
if (save_remap_read(&ctx->meta_remap_storage, ctx->fat_storage, ctx->header.fat_ivfc_header.level_headers[ctx->header.fat_ivfc_header.num_levels - 2].logical_offset, ctx->fat_ivfc_storage._length) != ctx->fat_ivfc_storage._length)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to read FAT storage from meta remap storage (IVFC)!", __func__);
strcat(strbuf, tmp);
goto out;
}
}
if (ctx->tool_ctx.action & ACTION_VERIFY)
{
if (save_filesystem_verify(ctx) == VALIDITY_INVALID)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: savefile FS verification failed!", __func__);
strcat(strbuf, tmp);
goto out;
}
}
/* Initialize core save filesystem. */
ctx->save_filesystem_core.base_storage = &ctx->core_data_ivfc_storage;
if (!save_filesystem_init(&ctx->save_filesystem_core, ctx->fat_storage, &ctx->header.save_header, &ctx->header.fat_header))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to initialize savefile FS!", __func__);
strcat(strbuf, tmp);
goto out;
}
success = true;
out:
if (!success) save_free_contexts(ctx);
return success;
}
bool save_process_header(save_ctx_t *ctx)
{
if (!ctx)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to process savefile header!", __func__);
return false;
}
if (ctx->header.layout.magic != MAGIC_DISF || ctx->header.duplex_header.magic != MAGIC_DPFS || \
ctx->header.data_ivfc_header.magic != MAGIC_IVFC || ctx->header.journal_header.magic != MAGIC_JNGL || \
ctx->header.save_header.magic != MAGIC_SAVE || ctx->header.main_remap_header.magic != MAGIC_RMAP || \
ctx->header.meta_remap_header.magic != MAGIC_RMAP)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: save header is corrupt!", __func__);
return false;
}
ctx->data_ivfc_master = ((u8*)&ctx->header + ctx->header.layout.ivfc_master_hash_offset_a);
ctx->fat_ivfc_master = ((u8*)&ctx->header + ctx->header.layout.fat_ivfc_master_hash_a);
u8 hash[0x20];
sha256CalculateHash(hash, &ctx->header.duplex_header, 0x3D00);
ctx->header_hash_validity = (memcmp(hash, ctx->header.layout.hash, 0x20) == 0 ? VALIDITY_VALID : VALIDITY_INVALID);
ctx->header.data_ivfc_header.num_levels = 5;
if (ctx->header.layout.version >= 0x50000) ctx->header.fat_ivfc_header.num_levels = 4;
return true;
}
void save_free_contexts(save_ctx_t *ctx)
{
if (!ctx) return;
if (ctx->data_remap_storage.segments)
{
if (ctx->data_remap_storage.header)
{
for(unsigned int i = 0; i < ctx->data_remap_storage.header->map_segment_count; i++)
{
if (ctx->data_remap_storage.segments[i].entries) free(ctx->data_remap_storage.segments[i].entries);
}
}
free(ctx->data_remap_storage.segments);
ctx->data_remap_storage.segments = NULL;
}
if (ctx->data_remap_storage.map_entries)
{
free(ctx->data_remap_storage.map_entries);
ctx->data_remap_storage.map_entries = NULL;
}
if (ctx->meta_remap_storage.segments)
{
if (ctx->meta_remap_storage.header)
{
for(unsigned int i = 0; i < ctx->meta_remap_storage.header->map_segment_count; i++)
{
if (ctx->meta_remap_storage.segments[i].entries) free(ctx->meta_remap_storage.segments[i].entries);
}
}
free(ctx->meta_remap_storage.segments);
ctx->meta_remap_storage.segments = NULL;
}
if (ctx->meta_remap_storage.map_entries)
{
free(ctx->meta_remap_storage.map_entries);
ctx->meta_remap_storage.map_entries = NULL;
}
if (ctx->duplex_storage.layers[0].bitmap.bitmap)
{
free(ctx->duplex_storage.layers[0].bitmap.bitmap);
ctx->duplex_storage.layers[0].bitmap.bitmap = NULL;
}
if (ctx->duplex_storage.layers[1].bitmap.bitmap)
{
free(ctx->duplex_storage.layers[1].bitmap.bitmap);
ctx->duplex_storage.layers[1].bitmap.bitmap = NULL;
}
if (ctx->duplex_storage.layers[1].bitmap_storage)
{
free(ctx->duplex_storage.layers[1].bitmap_storage);
ctx->duplex_storage.layers[1].bitmap_storage = NULL;
}
for(unsigned int i = 1; i < 3; i++)
{
if (ctx->duplex_layers[i].data_a)
{
free(ctx->duplex_layers[i].data_a);
ctx->duplex_layers[i].data_a = NULL;
}
if (ctx->duplex_layers[i].data_b)
{
free(ctx->duplex_layers[i].data_b);
ctx->duplex_layers[i].data_b = NULL;
}
}
if (ctx->journal_map_info.map_storage)
{
free(ctx->journal_map_info.map_storage);
ctx->journal_map_info.map_storage = NULL;
}
if (ctx->journal_storage.map.entries)
{
free(ctx->journal_storage.map.entries);
ctx->journal_storage.map.entries = NULL;
}
for(unsigned int i = 0; i < ctx->header.data_ivfc_header.num_levels - 1; i++)
{
if (ctx->core_data_ivfc_storage.integrity_storages[i].block_validities)
{
free(ctx->core_data_ivfc_storage.integrity_storages[i].block_validities);
ctx->core_data_ivfc_storage.integrity_storages[i].block_validities = NULL;
}
}
if (ctx->core_data_ivfc_storage.level_validities)
{
free(ctx->core_data_ivfc_storage.level_validities);
ctx->core_data_ivfc_storage.level_validities = NULL;
}
if (ctx->header.layout.version >= 0x50000)
{
for(unsigned int i = 0; i < ctx->header.fat_ivfc_header.num_levels - 1; i++)
{
if (ctx->fat_ivfc_storage.integrity_storages[i].block_validities)
{
free(ctx->fat_ivfc_storage.integrity_storages[i].block_validities);
ctx->fat_ivfc_storage.integrity_storages[i].block_validities = NULL;
}
}
}
if (ctx->fat_ivfc_storage.level_validities)
{
free(ctx->fat_ivfc_storage.level_validities);
ctx->fat_ivfc_storage.level_validities = NULL;
}
if (ctx->fat_storage)
{
free(ctx->fat_storage);
ctx->fat_storage = NULL;
}
}
bool readCertsFromSystemSave()
{
if (loadedCerts) return true;
FRESULT fr = FR_OK;
FIL *certSave = NULL;
save_ctx_t *save_ctx = NULL;
allocation_table_storage_ctx_t fat_storage = {0};
save_fs_list_entry_t entry = {0};
u64 internalCertSize = 0;
u8 i, j;
UINT br = 0;
u8 tmp_hash[0x20];
char tmp[NAME_BUF_LEN / 2] = {'\0'};
bool success = false, openSave = false, initSaveCtx = false;
certSave = calloc(1, sizeof(FIL));
if (!certSave)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: unable to allocate memory for FatFs file descriptor!", __func__);
goto out;
}
fr = f_open(certSave, BIS_CERT_SAVE_NAME, FA_READ | FA_OPEN_EXISTING);
if (fr != FR_OK)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to open \"%s\" savefile from BIS System partition! (%u)", __func__, BIS_CERT_SAVE_NAME, fr);
goto out;
}
openSave = true;
save_ctx = calloc(1, sizeof(save_ctx_t));
if (!save_ctx)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to allocate memory for savefile context!", __func__);
goto out;
}
save_ctx->file = certSave;
save_ctx->tool_ctx.action = 0;
initSaveCtx = save_process(save_ctx);
if (!initSaveCtx)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to process system savefile!", __func__);
strcat(strbuf, tmp);
goto out;
}
// 0 = Root, 1 = Common, 2 = Personalized
for(i = 0; i < 3; i++)
{
char cert_path[SAVE_FS_LIST_MAX_NAME_LENGTH * 2] = {'\0'};
u64 cert_expected_size = (i == 0 ? ETICKET_CA_CERT_SIZE : ETICKET_XS_CERT_SIZE);
u8 *cert_data_ptr = (i == 0 ? cert_root_data : (i == 1 ? cert_common_data : cert_personalized_data));
u8 cert_expected_hash[SHA256_HASH_SIZE];
memset(&entry, 0, sizeof(save_fs_list_entry_t));
memset(&fat_storage, 0, sizeof(allocation_table_storage_ctx_t));
bool getFileEntry = false;
if (i < 2)
{
snprintf(cert_path, MAX_CHARACTERS(cert_path), (i == 0 ? cert_CA00000003_path : cert_XS00000020_path));
memcpy(cert_expected_hash, (i == 0 ? cert_CA00000003_hash : cert_XS00000020_hash), SHA256_HASH_SIZE);
getFileEntry = save_hierarchical_file_table_get_file_entry_by_path(&save_ctx->save_filesystem_core.file_table, cert_path, &entry);
} else {
// Try loading multiple personalized certificates until we hit the right one
for(j = 0; j < personalized_cert_count; j++)
{
switch(j)
{
case 0: // < 9.0.0
snprintf(cert_path, MAX_CHARACTERS(cert_path), cert_XS00000021_path);
memcpy(cert_expected_hash, cert_XS00000021_hash, SHA256_HASH_SIZE);
break;
case 1: // >= 9.0.0
snprintf(cert_path, MAX_CHARACTERS(cert_path), cert_XS00000024_path);
memcpy(cert_expected_hash, cert_XS00000024_hash, SHA256_HASH_SIZE);
break;
default:
break;
}
strbuf[0] = '\0';
getFileEntry = save_hierarchical_file_table_get_file_entry_by_path(&save_ctx->save_filesystem_core.file_table, cert_path, &entry);
if (getFileEntry) break;
}
}
if (!getFileEntry)
{
// Only print the error if we're dealing with either the root or common certificates. We may be dealing with a console without a personalized certificate
if (i < 2)
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to get file entry for \"%s\" in system savefile!", __func__, cert_path);
strcat(strbuf, tmp);
} else {
success = loadedCerts = true;
}
goto out;
}
if (!save_open_fat_storage(&save_ctx->save_filesystem_core, &fat_storage, entry.value.save_file_info.start_block))
{
snprintf(tmp, MAX_CHARACTERS(tmp), "\n%s: failed to open FAT storage at block 0x%X for \"%s\" in system savefile!", __func__, entry.value.save_file_info.start_block, cert_path);
strcat(strbuf, tmp);
goto out;
}
internalCertSize = entry.value.save_file_info.length;
if (internalCertSize != cert_expected_size)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid size for \"%s\" in system savefile! (%lu != %lu)", __func__, cert_path, internalCertSize, cert_expected_size);
goto out;
}
br = save_allocation_table_storage_read(&fat_storage, cert_data_ptr, 0, cert_expected_size);
if (br != (UINT)cert_expected_size)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: failed to read \"%s\" from system savefile!", __func__, cert_path);
goto out;
}
sha256CalculateHash(tmp_hash, cert_data_ptr, cert_expected_size);
if (memcmp(tmp_hash, cert_expected_hash, 0x20) != 0)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid hash for \"%s\" in system savefile!", __func__, cert_path);
goto out;
}
}
success = loadedCerts = personalizedCertAvailable = true;
out:
if (save_ctx)
{
if (initSaveCtx) save_free_contexts(save_ctx);
free(save_ctx);
}
if (certSave)
{
if (openSave) f_close(certSave);
free(certSave);
}
return success;
}
bool retrieveCertData(u8 *out_cert, bool personalized)
{
if (!out_cert)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: invalid parameters to retrieve %s ticket certificate chain.", __func__, (!personalized ? "common" : "personalized"));
return false;
}
if (!readCertsFromSystemSave()) return false;
if (personalized && !personalizedCertAvailable)
{
snprintf(strbuf, MAX_CHARACTERS(strbuf), "%s: personalized ticket RSA certificate requested but unavailable in ES system savefile!", __func__);
return false;
}
memcpy(out_cert, cert_root_data, ETICKET_CA_CERT_SIZE);
memcpy(out_cert + ETICKET_CA_CERT_SIZE, (!personalized ? cert_common_data : cert_personalized_data), ETICKET_XS_CERT_SIZE);
return true;
}