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nxdumptool/source/core/gamecard.c
Pablo Curiel e1df86fb27 Fix building with latest libnx + QoL changes.
libnx now implements fsDeviceOperatorGetGameCardIdSet(), so I got rid of my own implementation.

Other changes include:

* cnmt: add cnmtVerifyContentHash().

* defines: add SHA256_HASH_STR_SIZE.

* fs_ext: add FsCardId1MakerCode, FsCardId1MemoryType and FsCardId2CardType enums.
* fs_ext: update FsCardId* structs.

* gamecard: change all package_id definitions from u64 -> u8[0x8].
* gamecard: fix misleading struct member names in GameCardHeader.
* gamecard: rename gamecardGetIdSet() -> gamecardGetCardIdSet().

* gamecard_tab: fix Package ID printing.
* gamecard_tab: add Card ID Set printing.

* host: add executable flag to Python scripts.

* keys: detect if we're dealing with a wiped eTicket RSA device key (e.g. via set:cal blanking). If so, the application will still launch, but all operations related to personalized titlekey crypto are disabled.

* pfs: rename PartitionFileSystemFileContext -> PartitionFileSystemImageContext and propagate the change throughout the codebase.
* pfs: rename PFS_FULL_HEADER_ALIGNMENT -> PFS_HEADER_PADDING_ALIGNMENT and update pfsWriteImageContextHeaderToMemoryBuffer() accordingly.

* poc: print certain button prompts with reversed colors, in the hopes of getting the user's attention.
* poc: NSP, Ticket and NCA submenus for updates and DLC updates now display the highest available title by default.
* poc: simplified output path generation for extracted NCA FS section dumps.
* poc: handle edge cases where a specific NCA from an update has no matching equivalent by type/ID offset in its base title (e.g. Fall Guys' HtmlDocument NCA).
* poc: implement NCA checksum validation while generating NSP dumps.

* romfs: update romfsInitializeContext() to allow its base_nca_fs_ctx argument to be NULL.

* usb: use USB_BOS_SIZE only once.

* workflow: update commit hash referenced by "rewrite-prerelease" tag on update.
2023-11-03 02:22:47 +01:00

1376 lines
44 KiB
C

/*
* gamecard.c
*
* 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/>.
*/
#include "nxdt_utils.h"
#include "mem.h"
#include "gamecard.h"
#include "keys.h"
#define GAMECARD_HFS0_MAGIC 0x48465330 /* "HFS0". */
#define GAMECARD_READ_BUFFER_SIZE 0x800000 /* 8 MiB. */
#define GAMECARD_ACCESS_DELAY 3 /* Seconds. */
#define GAMECARD_UNUSED_AREA_BLOCK_SIZE 0x24
#define GAMECARD_UNUSED_AREA_SIZE(x) (((x) / GAMECARD_PAGE_SIZE) * GAMECARD_UNUSED_AREA_BLOCK_SIZE)
#define GAMECARD_STORAGE_AREA_NAME(x) ((x) == GameCardStorageArea_Normal ? "normal" : ((x) == GameCardStorageArea_Secure ? "secure" : "none"))
#define LAFW_MAGIC 0x4C414657 /* "LAFW". */
/* Type definitions. */
typedef enum {
GameCardStorageArea_None = 0,
GameCardStorageArea_Normal = 1,
GameCardStorageArea_Secure = 2
} GameCardStorageArea;
typedef enum {
GameCardCapacity_1GiB = BITL(30),
GameCardCapacity_2GiB = BITL(31),
GameCardCapacity_4GiB = BITL(32),
GameCardCapacity_8GiB = BITL(33),
GameCardCapacity_16GiB = BITL(34),
GameCardCapacity_32GiB = BITL(35)
} GameCardCapacity;
/* Global variables. */
static Mutex g_gameCardMutex = 0;
static bool g_gameCardInterfaceInit = false;
static FsDeviceOperator g_deviceOperator = {0};
static FsEventNotifier g_gameCardEventNotifier = {0};
static Event g_gameCardKernelEvent = {0};
static bool g_openDeviceOperator = false, g_openEventNotifier = false, g_loadKernelEvent = false;
static LotusAsicFirmwareBlob *g_lafwBlob = NULL;
static u64 g_lafwVersion = 0;
static Thread g_gameCardDetectionThread = {0};
static UEvent g_gameCardDetectionThreadExitEvent = {0}, g_gameCardStatusChangeEvent = {0};
static bool g_gameCardDetectionThreadCreated = false;
static GameCardStatus g_gameCardStatus = GameCardStatus_NotInserted;
static FsGameCardHandle g_gameCardHandle = {0};
static FsStorage g_gameCardStorage = {0};
static u8 g_gameCardCurrentStorageArea = GameCardStorageArea_None;
static u8 *g_gameCardReadBuf = NULL;
static GameCardHeader g_gameCardHeader = {0};
static GameCardInfo g_gameCardInfoArea = {0};
static u64 g_gameCardNormalAreaSize = 0, g_gameCardSecureAreaSize = 0, g_gameCardTotalSize = 0;
static u64 g_gameCardCapacity = 0;
static u32 g_gameCardHfsCount = 0;
static HashFileSystemContext **g_gameCardHfsCtx = NULL;
static MemoryLocation g_fsProgramMemory = {
.program_id = FS_SYSMODULE_TID,
.mask = 0,
.data = NULL,
.data_size = 0
};
static const char *g_gameCardHosVersionStrings[GameCardFwVersion_Count] = {
[GameCardFwVersion_ForDev] = "1.0.0",
[GameCardFwVersion_Since100NUP] = "1.0.0",
[GameCardFwVersion_Since400NUP] = "4.0.0",
[GameCardFwVersion_Since900NUP] = "9.0.0",
[GameCardFwVersion_Since1100NUP] = "11.0.0",
[GameCardFwVersion_Since1200NUP] = "12.0.0"
};
static const char *g_gameCardCompatibilityTypeStrings[GameCardCompatibilityType_Count] = {
[GameCardCompatibilityType_Normal] = "Normal",
[GameCardCompatibilityType_Terra] = "Terra"
};
static const char *g_lafwDeviceTypeStrings[LotusAsicDeviceType_Count] = {
[LotusAsicDeviceType_Test] = "Test",
[LotusAsicDeviceType_Dev] = "Dev",
[LotusAsicDeviceType_Prod] = "Prod",
[LotusAsicDeviceType_Prod2Dev] = "Prod2Dev"
};
/* Function prototypes. */
static bool gamecardReadLotusAsicFirmwareBlob(void);
static bool gamecardCreateDetectionThread(void);
static void gamecardDestroyDetectionThread(void);
static void gamecardDetectionThreadFunc(void *arg);
NX_INLINE bool gamecardIsInserted(void);
static void gamecardLoadInfo(void);
static void gamecardFreeInfo(bool clear_status);
static bool gamecardReadHeader(void);
static bool _gamecardGetDecryptedCardInfoArea(void);
static bool gamecardReadSecurityInformation(GameCardSecurityInformation *out);
static bool gamecardGetHandleAndStorage(u32 partition);
NX_INLINE void gamecardCloseHandle(void);
static bool gamecardOpenStorageArea(u8 area);
static bool gamecardReadStorageArea(void *out, u64 read_size, u64 offset);
static void gamecardCloseStorageArea(void);
static bool gamecardGetStorageAreasSizes(void);
NX_INLINE u64 gamecardGetCapacityFromRomSizeValue(u8 rom_size);
static HashFileSystemContext *gamecardInitializeHashFileSystemContext(const char *name, u64 offset, u64 size, u8 *hash, u64 hash_target_offset, u32 hash_target_size);
static HashFileSystemContext *_gamecardGetHashFileSystemContext(u8 hfs_partition_type);
bool gamecardInitialize(void)
{
Result rc = 0;
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
ret = g_gameCardInterfaceInit;
if (ret) break;
/* Allocate memory for the gamecard read buffer. */
g_gameCardReadBuf = malloc(GAMECARD_READ_BUFFER_SIZE);
if (!g_gameCardReadBuf)
{
LOG_MSG_ERROR("Unable to allocate memory for the gamecard read buffer!");
break;
}
/* Open device operator. */
rc = fsOpenDeviceOperator(&g_deviceOperator);
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsOpenDeviceOperator failed! (0x%X).", rc);
break;
}
g_openDeviceOperator = true;
/* Open gamecard detection event notifier. */
rc = fsOpenGameCardDetectionEventNotifier(&g_gameCardEventNotifier);
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsOpenGameCardDetectionEventNotifier failed! (0x%X)", rc);
break;
}
g_openEventNotifier = true;
/* Retrieve gamecard detection kernel event. */
rc = fsEventNotifierGetEventHandle(&g_gameCardEventNotifier, &g_gameCardKernelEvent, true);
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsEventNotifierGetEventHandle failed! (0x%X)", rc);
break;
}
g_loadKernelEvent = true;
/* Create user-mode exit event. */
ueventCreate(&g_gameCardDetectionThreadExitEvent, true);
/* Create user-mode gamecard status change event. */
ueventCreate(&g_gameCardStatusChangeEvent, true);
/* Retrieve LAFW blob. */
if (!gamecardReadLotusAsicFirmwareBlob()) break;
/* Create gamecard detection thread. */
if (!(g_gameCardDetectionThreadCreated = gamecardCreateDetectionThread())) break;
/* Update flags. */
ret = g_gameCardInterfaceInit = true;
}
return ret;
}
void gamecardExit(void)
{
SCOPED_LOCK(&g_gameCardMutex)
{
/* Destroy gamecard detection thread. */
if (g_gameCardDetectionThreadCreated)
{
gamecardDestroyDetectionThread();
g_gameCardDetectionThreadCreated = false;
}
/* Free LAFW blob buffer. */
if (g_lafwBlob)
{
free(g_lafwBlob);
g_lafwBlob = NULL;
}
/* Close gamecard detection kernel event. */
if (g_loadKernelEvent)
{
eventClose(&g_gameCardKernelEvent);
g_loadKernelEvent = false;
}
/* Close gamecard detection event notifier. */
if (g_openEventNotifier)
{
fsEventNotifierClose(&g_gameCardEventNotifier);
g_openEventNotifier = false;
}
/* Close device operator. */
if (g_openDeviceOperator)
{
fsDeviceOperatorClose(&g_deviceOperator);
g_openDeviceOperator = false;
}
/* Free gamecard read buffer. */
if (g_gameCardReadBuf)
{
free(g_gameCardReadBuf);
g_gameCardReadBuf = NULL;
}
g_gameCardInterfaceInit = false;
}
}
UEvent *gamecardGetStatusChangeUserEvent(void)
{
UEvent *event = NULL;
SCOPED_LOCK(&g_gameCardMutex)
{
if (g_gameCardInterfaceInit) event = &g_gameCardStatusChangeEvent;
}
return event;
}
u8 gamecardGetStatus(void)
{
u8 status = GameCardStatus_Processing;
SCOPED_TRY_LOCK(&g_gameCardMutex)
{
if (g_gameCardInterfaceInit) status = g_gameCardStatus;
}
return status;
}
/* Read full FS program memory to retrieve the GameCardSecurityInformation block. */
/* In FS program memory, this is returned by Lotus command "ChangeToSecureMode" (0xF). */
/* This means it is only available *after* the gamecard secure area has been mounted, which is taken care of in gamecardReadSecurityInformation(). */
bool gamecardGetSecurityInformation(GameCardSecurityInformation *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex) ret = gamecardReadSecurityInformation(out);
return ret;
}
bool gamecardGetCardIdSet(FsGameCardIdSet *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
if (!g_gameCardInterfaceInit || g_gameCardStatus != GameCardStatus_InsertedAndInfoLoaded || !out) break;
Result rc = fsDeviceOperatorGetGameCardIdSet(&g_deviceOperator, out, sizeof(FsGameCardIdSet), (s64)sizeof(FsGameCardIdSet));
if (R_FAILED(rc)) LOG_MSG_ERROR("fsDeviceOperatorGetGameCardIdSet failed! (0x%X)", rc);
ret = R_SUCCEEDED(rc);
}
return ret;
}
bool gamecardGetLotusAsicFirmwareBlob(LotusAsicFirmwareBlob *out_lafw_blob, u64 *out_lafw_version)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
if (!g_gameCardInterfaceInit || !g_lafwBlob || (!out_lafw_blob && !out_lafw_version)) break;
/* Copy LAFW blob data. */
if (out_lafw_blob) memcpy(out_lafw_blob, g_lafwBlob, sizeof(LotusAsicFirmwareBlob));
/* Copy LAFW version. */
if (out_lafw_version) *out_lafw_version = g_lafwVersion;
ret = true;
}
return ret;
}
bool gamecardReadStorage(void *out, u64 read_size, u64 offset)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex) ret = gamecardReadStorageArea(out, read_size, offset);
return ret;
}
bool gamecardGetHeader(GameCardHeader *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
ret = (g_gameCardInterfaceInit && g_gameCardStatus == GameCardStatus_InsertedAndInfoLoaded && out);
if (ret) memcpy(out, &g_gameCardHeader, sizeof(GameCardHeader));
}
return ret;
}
bool gamecardGetDecryptedCardInfoArea(GameCardInfo *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
ret = (g_gameCardInterfaceInit && g_gameCardStatus == GameCardStatus_InsertedAndInfoLoaded && out);
if (ret) memcpy(out, &g_gameCardInfoArea, sizeof(GameCardInfo));
}
return ret;
}
bool gamecardGetCertificate(FsGameCardCertificate *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
if (!g_gameCardInterfaceInit || g_gameCardStatus != GameCardStatus_InsertedAndInfoLoaded || !g_gameCardHandle.value || !out) break;
/* Read the gamecard certificate using the official IPC call. */
Result rc = fsDeviceOperatorGetGameCardDeviceCertificate(&g_deviceOperator, &g_gameCardHandle, out);
if (R_FAILED(rc)) LOG_MSG_ERROR("fsDeviceOperatorGetGameCardDeviceCertificate failed! (0x%X)", rc);
ret = R_SUCCEEDED(rc);
}
return ret;
}
bool gamecardGetTotalSize(u64 *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
ret = (g_gameCardInterfaceInit && g_gameCardStatus == GameCardStatus_InsertedAndInfoLoaded && out);
if (ret) *out = g_gameCardTotalSize;
}
return ret;
}
bool gamecardGetTrimmedSize(u64 *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
ret = (g_gameCardInterfaceInit && g_gameCardStatus == GameCardStatus_InsertedAndInfoLoaded && out);
if (ret) *out = (sizeof(GameCardHeader) + GAMECARD_PAGE_OFFSET(g_gameCardHeader.valid_data_end_page));
}
return ret;
}
bool gamecardGetRomCapacity(u64 *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
ret = (g_gameCardInterfaceInit && g_gameCardStatus == GameCardStatus_InsertedAndInfoLoaded && out);
if (ret) *out = g_gameCardCapacity;
}
return ret;
}
bool gamecardGetBundledFirmwareUpdateVersion(Version *out)
{
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
if (!g_gameCardInterfaceInit || g_gameCardStatus != GameCardStatus_InsertedAndInfoLoaded || !g_gameCardHandle.value || !out) break;
u64 update_id = 0;
u32 update_version = 0;
Result rc = fsDeviceOperatorUpdatePartitionInfo(&g_deviceOperator, &g_gameCardHandle, &update_version, &update_id);
if (R_FAILED(rc)) LOG_MSG_ERROR("fsDeviceOperatorUpdatePartitionInfo failed! (0x%X)", rc);
ret = (R_SUCCEEDED(rc) && update_id == GAMECARD_UPDATE_TID);
if (ret) out->value = update_version;
}
return ret;
}
bool gamecardGetHashFileSystemContext(u8 hfs_partition_type, HashFileSystemContext *out)
{
if (hfs_partition_type < HashFileSystemPartitionType_Root || hfs_partition_type >= HashFileSystemPartitionType_Count || !out)
{
LOG_MSG_ERROR("Invalid parameters!");
return false;
}
bool ret = false;
/* Free Hash FS context. */
hfsFreeContext(out);
SCOPED_LOCK(&g_gameCardMutex)
{
/* Get pointer to the Hash FS context for the requested partition. */
HashFileSystemContext *hfs_ctx = _gamecardGetHashFileSystemContext(hfs_partition_type);
if (!hfs_ctx) break;
/* Fill Hash FS context. */
out->name = strdup(hfs_ctx->name);
if (!out->name)
{
LOG_MSG_ERROR("Failed to duplicate Hash FS partition name! (%s).", hfs_ctx->name);
break;
}
out->type = hfs_ctx->type;
out->offset = hfs_ctx->offset;
out->size = hfs_ctx->size;
out->header_size = hfs_ctx->header_size;
out->header = calloc(hfs_ctx->header_size, sizeof(u8));
if (!out->header)
{
LOG_MSG_ERROR("Failed to duplicate Hash FS partition header! (%s).", hfs_ctx->name);
break;
}
memcpy(out->header, hfs_ctx->header, hfs_ctx->header_size);
/* Update flag. */
ret = true;
}
if (!ret) hfsFreeContext(out);
return ret;
}
bool gamecardGetHashFileSystemEntryInfoByName(u8 hfs_partition_type, const char *entry_name, u64 *out_offset, u64 *out_size)
{
if (hfs_partition_type < HashFileSystemPartitionType_Root || hfs_partition_type >= HashFileSystemPartitionType_Count || !entry_name || !*entry_name || (!out_offset && !out_size))
{
LOG_MSG_ERROR("Invalid parameters!");
return false;
}
bool ret = false;
SCOPED_LOCK(&g_gameCardMutex)
{
/* Get pointer to the Hash FS context for the requested partition. */
HashFileSystemContext *hfs_ctx = _gamecardGetHashFileSystemContext(hfs_partition_type);
if (!hfs_ctx) break;
/* Get Hash FS entry by name. */
HashFileSystemEntry *hfs_entry = hfsGetEntryByName(hfs_ctx, entry_name);
if (!hfs_entry) break;
/* Update output variables. */
if (out_offset) *out_offset = (hfs_ctx->offset + hfs_ctx->header_size + hfs_entry->offset);
if (out_size) *out_size = hfs_entry->size;
/* Update flag. */
ret = true;
}
return ret;
}
const char *gamecardGetRequiredHosVersionString(u64 fw_version)
{
return (fw_version < GameCardFwVersion_Count ? g_gameCardHosVersionStrings[fw_version] : NULL);
}
const char *gamecardGetCompatibilityTypeString(u8 compatibility_type)
{
return (compatibility_type < GameCardCompatibilityType_Count ? g_gameCardCompatibilityTypeStrings[compatibility_type] : NULL);
}
const char *gamecardGetLafwTypeString(u32 fw_type)
{
const char *type = NULL;
switch(fw_type)
{
case LotusAsicFirmwareType_ReadFw:
type = "ReadFw";
break;
case LotusAsicFirmwareType_ReadDevFw:
type = "ReadDevFw";
break;
case LotusAsicFirmwareType_WriterFw:
type = "WriterFw";
break;
case LotusAsicFirmwareType_RmaFw:
type = "RmaFw";
break;
default:
break;
}
return type;
}
const char *gamecardGetLafwDeviceTypeString(u64 device_type)
{
return (device_type < LotusAsicDeviceType_Count ? g_lafwDeviceTypeStrings[device_type] : NULL);
}
static bool gamecardReadLotusAsicFirmwareBlob(void)
{
u64 fw_version = 0;
bool ret = false, found = false, dev_unit = utilsIsDevelopmentUnit();
/* Allocate memory for the LAFW blob. */
g_lafwBlob = calloc(1, sizeof(LotusAsicFirmwareBlob));
if (!g_lafwBlob)
{
LOG_MSG_ERROR("Failed to allocate memory for LAFW blob!");
goto end;
}
/* Temporarily set the segment mask to .data. */
g_fsProgramMemory.mask = MemoryProgramSegmentType_Data;
/* Retrieve FS .data segment memory dump. */
if (!memRetrieveProgramMemorySegment(&g_fsProgramMemory))
{
LOG_MSG_ERROR("Failed to retrieve FS .data segment dump!");
goto end;
}
/* Look for the LAFW ReadFw blob in the FS .data segment memory dump. */
for(u64 offset = 0; offset < g_fsProgramMemory.data_size; offset++)
{
if ((g_fsProgramMemory.data_size - offset) < sizeof(LotusAsicFirmwareBlob)) break;
LotusAsicFirmwareBlob *lafw_blob = (LotusAsicFirmwareBlob*)(g_fsProgramMemory.data + offset);
u32 magic = __builtin_bswap32(lafw_blob->magic), fw_type = lafw_blob->fw_type;
if (magic == LAFW_MAGIC && ((!dev_unit && fw_type == LotusAsicFirmwareType_ReadFw) || (dev_unit && fw_type == LotusAsicFirmwareType_ReadDevFw)))
{
/* Jackpot. */
memcpy(g_lafwBlob, lafw_blob, sizeof(LotusAsicFirmwareBlob));
fw_version = lafw_blob->fw_version;
found = true;
break;
}
}
if (!found)
{
LOG_MSG_ERROR("Unable to locate Lotus %s blob in FS .data segment!", dev_unit ? "ReadDevFw" : "ReadFw");
goto end;
}
/* Convert LAFW version bitmask to an integer. */
g_lafwVersion = 0;
while(fw_version)
{
g_lafwVersion += (fw_version & 1);
fw_version >>= 1;
}
LOG_MSG_INFO("LAFW version: %lu.", g_lafwVersion);
/* Update flag. */
ret = true;
end:
memFreeMemoryLocation(&g_fsProgramMemory);
g_fsProgramMemory.mask = MemoryProgramSegmentType_None;
return ret;
}
static bool gamecardCreateDetectionThread(void)
{
if (!utilsCreateThread(&g_gameCardDetectionThread, gamecardDetectionThreadFunc, NULL, 1))
{
LOG_MSG_ERROR("Failed to create gamecard detection thread!");
return false;
}
return true;
}
static void gamecardDestroyDetectionThread(void)
{
/* Signal the exit event to terminate the gamecard detection thread. */
ueventSignal(&g_gameCardDetectionThreadExitEvent);
/* Wait for the gamecard detection thread to exit. */
utilsJoinThread(&g_gameCardDetectionThread);
}
static void gamecardDetectionThreadFunc(void *arg)
{
(void)arg;
Result rc = 0;
int idx = 0;
Waiter gamecard_event_waiter = waiterForEvent(&g_gameCardKernelEvent);
Waiter exit_event_waiter = waiterForUEvent(&g_gameCardDetectionThreadExitEvent);
/* Retrieve initial gamecard insertion status. */
/* Load gamecard info right away if a gamecard is inserted, then signal the user mode gamecard status change event. */
SCOPED_LOCK(&g_gameCardMutex)
{
if (gamecardIsInserted()) gamecardLoadInfo();
ueventSignal(&g_gameCardStatusChangeEvent);
}
while(true)
{
/* Wait until an event is triggered. */
rc = waitMulti(&idx, -1, gamecard_event_waiter, exit_event_waiter);
if (R_FAILED(rc)) continue;
/* Exit event triggered. */
if (idx == 1) break;
SCOPED_LOCK(&g_gameCardMutex)
{
/* Free gamecard info before proceeding. */
gamecardFreeInfo(true);
/* Retrieve current gamecard insertion status. */
/* Only proceed if we're dealing with a status change. */
if (gamecardIsInserted())
{
/* Don't access the gamecard immediately to avoid conflicts with HOS / sysmodules. */
utilsSleep(GAMECARD_ACCESS_DELAY);
/* Load gamecard info. */
gamecardLoadInfo();
}
/* Signal user mode gamecard status change event. */
ueventSignal(&g_gameCardStatusChangeEvent);
}
}
/* Free gamecard info and close gamecard handle. */
gamecardFreeInfo(true);
threadExit();
}
NX_INLINE bool gamecardIsInserted(void)
{
bool inserted = false;
Result rc = fsDeviceOperatorIsGameCardInserted(&g_deviceOperator, &inserted);
if (R_FAILED(rc)) LOG_MSG_ERROR("fsDeviceOperatorIsGameCardInserted failed! (0x%X)", rc);
return (R_SUCCEEDED(rc) && inserted);
}
static void gamecardLoadInfo(void)
{
if (g_gameCardStatus == GameCardStatus_InsertedAndInfoLoaded) return;
HashFileSystemContext *root_hfs_ctx = NULL;
u32 root_hfs_entry_count = 0, root_hfs_name_table_size = 0;
char *root_hfs_name_table = NULL;
/* Set initial gamecard status. */
g_gameCardStatus = GameCardStatus_InsertedAndInfoNotLoaded;
/* Read gamecard header. */
/* This step *will* fail if the running CFW enabled the "nogc" patch. */
/* gamecardGetHandleAndStorage() takes care of updating the gamecard status accordingly if this happens. */
if (!gamecardReadHeader()) goto end;
/* Get decrypted CardInfo area from header. */
if (!_gamecardGetDecryptedCardInfoArea()) goto end;
/* Check if we meet the Lotus ASIC firmware (LAFW) version requirement. */
if (g_lafwVersion < g_gameCardInfoArea.fw_version)
{
LOG_MSG_ERROR("LAFW version doesn't meet gamecard requirement! (%lu < %lu).", g_lafwVersion, g_gameCardInfoArea.fw_version);
g_gameCardStatus = GameCardStatus_LotusAsicFirmwareUpdateRequired;
goto end;
}
/* Retrieve gamecard storage area sizes. */
/* gamecardReadStorageArea() actually checks if the storage area sizes are greater than zero, so we must perform this step. */
if (!gamecardGetStorageAreasSizes())
{
LOG_MSG_ERROR("Failed to retrieve gamecard storage area sizes!");
goto end;
}
/* Get gamecard capacity. */
g_gameCardCapacity = gamecardGetCapacityFromRomSizeValue(g_gameCardHeader.rom_size);
if (!g_gameCardCapacity)
{
LOG_MSG_ERROR("Invalid gamecard capacity value! (0x%02X).", g_gameCardHeader.rom_size);
goto end;
}
if (utilsGetCustomFirmwareType() == UtilsCustomFirmwareType_SXOS)
{
/* The total size for the secure storage area is maxed out under SX OS. */
/* Let's try to calculate it manually. */
g_gameCardSecureAreaSize = (g_gameCardCapacity - (g_gameCardNormalAreaSize + GAMECARD_UNUSED_AREA_SIZE(g_gameCardCapacity)));
}
/* Initialize Hash FS context for the root partition. */
root_hfs_ctx = gamecardInitializeHashFileSystemContext(NULL, g_gameCardHeader.partition_fs_header_address, 0, g_gameCardHeader.partition_fs_header_hash, 0, g_gameCardHeader.partition_fs_header_size);
if (!root_hfs_ctx) goto end;
/* Calculate total Hash FS partition count. */
root_hfs_entry_count = hfsGetEntryCount(root_hfs_ctx);
g_gameCardHfsCount = (root_hfs_entry_count + 1);
/* Allocate Hash FS context pointer array. */
g_gameCardHfsCtx = calloc(g_gameCardHfsCount, sizeof(HashFileSystemContext*));
if (!g_gameCardHfsCtx)
{
LOG_MSG_ERROR("Unable to allocate Hash FS context pointer array! (%u).", g_gameCardHfsCount);
goto end;
}
/* Set root partition context as the first pointer. */
g_gameCardHfsCtx[0] = root_hfs_ctx;
/* Get root partition name table. */
root_hfs_name_table_size = ((HashFileSystemHeader*)root_hfs_ctx->header)->name_table_size;
root_hfs_name_table = hfsGetNameTable(root_hfs_ctx);
/* Initialize Hash FS contexts for the child partitions. */
for(u32 i = 0; i < root_hfs_entry_count; i++)
{
HashFileSystemEntry *hfs_entry = hfsGetEntryByIndex(root_hfs_ctx, i);
char *hfs_entry_name = (root_hfs_name_table + hfs_entry->name_offset);
u64 hfs_entry_offset = (root_hfs_ctx->offset + root_hfs_ctx->header_size + hfs_entry->offset);
if (hfs_entry->name_offset >= root_hfs_name_table_size || !*hfs_entry_name)
{
LOG_MSG_ERROR("Invalid name for root Hash FS partition entry #%u!", i);
goto end;
}
g_gameCardHfsCtx[i + 1] = gamecardInitializeHashFileSystemContext(hfs_entry_name, hfs_entry_offset, hfs_entry->size, hfs_entry->hash, hfs_entry->hash_target_offset, hfs_entry->hash_target_size);
if (!g_gameCardHfsCtx[i + 1]) goto end;
}
/* Update gamecard status. */
g_gameCardStatus = GameCardStatus_InsertedAndInfoLoaded;
end:
if (g_gameCardStatus != GameCardStatus_InsertedAndInfoLoaded)
{
if (!g_gameCardHfsCtx && root_hfs_ctx)
{
hfsFreeContext(root_hfs_ctx);
free(root_hfs_ctx);
}
gamecardFreeInfo(false);
}
}
static void gamecardFreeInfo(bool clear_status)
{
memset(&g_gameCardHeader, 0, sizeof(GameCardHeader));
memset(&g_gameCardInfoArea, 0, sizeof(GameCardInfo));
g_gameCardNormalAreaSize = g_gameCardSecureAreaSize = g_gameCardTotalSize = 0;
g_gameCardCapacity = 0;
if (g_gameCardHfsCtx)
{
for(u32 i = 0; i < g_gameCardHfsCount; i++)
{
HashFileSystemContext *cur_hfs_ctx = g_gameCardHfsCtx[i];
if (cur_hfs_ctx)
{
hfsFreeContext(cur_hfs_ctx);
free(cur_hfs_ctx);
}
}
free(g_gameCardHfsCtx);
g_gameCardHfsCtx = NULL;
}
g_gameCardHfsCount = 0;
gamecardCloseStorageArea();
if (clear_status) g_gameCardStatus = GameCardStatus_NotInserted;
}
static bool gamecardReadHeader(void)
{
/* Open normal storage area. */
if (!gamecardOpenStorageArea(GameCardStorageArea_Normal))
{
LOG_MSG_ERROR("Failed to open normal storage area!");
return false;
}
/* Read gamecard header. */
/* This step doesn't rely on gamecardReadStorageArea() because of its dependence on storage area sizes (which we haven't retrieved). */
Result rc = fsStorageRead(&g_gameCardStorage, 0, &g_gameCardHeader, sizeof(GameCardHeader));
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsStorageRead failed to read gamecard header! (0x%X).", rc);
return false;
}
LOG_DATA_DEBUG(&g_gameCardHeader, sizeof(GameCardHeader), "Gamecard header dump:");
/* Check magic word from gamecard header. */
if (__builtin_bswap32(g_gameCardHeader.magic) != GAMECARD_HEAD_MAGIC)
{
LOG_MSG_ERROR("Invalid gamecard header magic word! (0x%08X).", __builtin_bswap32(g_gameCardHeader.magic));
return false;
}
return true;
}
static bool _gamecardGetDecryptedCardInfoArea(void)
{
const u8 *card_info_key = NULL;
u8 card_info_iv[AES_128_KEY_SIZE] = {0};
Aes128CbcContext aes_ctx = {0};
/* Retrieve CardInfo area key. */
card_info_key = keysGetGameCardInfoKey();
if (!card_info_key)
{
LOG_MSG_ERROR("Failed to retrieve CardInfo area key!");
return false;
}
/* Reverse CardInfo IV. */
for(u8 i = 0; i < AES_128_KEY_SIZE; i++) card_info_iv[i] = g_gameCardHeader.card_info_iv[AES_128_KEY_SIZE - i - 1];
/* Initialize AES-128-CBC context. */
aes128CbcContextCreate(&aes_ctx, card_info_key, card_info_iv, false);
/* Decrypt CardInfo area. */
aes128CbcDecrypt(&aes_ctx, &g_gameCardInfoArea, &(g_gameCardHeader.card_info), sizeof(GameCardInfo));
LOG_DATA_DEBUG(&g_gameCardInfoArea, sizeof(GameCardInfo), "Gamecard CardInfo area dump:");
return true;
}
static bool gamecardReadSecurityInformation(GameCardSecurityInformation *out)
{
if (!g_gameCardInterfaceInit || g_gameCardStatus != GameCardStatus_InsertedAndInfoLoaded || !out)
{
LOG_MSG_ERROR("Invalid parameters!");
return false;
}
/* Clear output. */
memset(out, 0, sizeof(GameCardSecurityInformation));
/* Open secure storage area. */
if (!gamecardOpenStorageArea(GameCardStorageArea_Secure))
{
LOG_MSG_ERROR("Failed to open secure storage area!");
return false;
}
bool found = false;
u8 tmp_hash[SHA256_HASH_SIZE] = {0};
/* Retrieve full FS program memory dump. */
if (!memRetrieveFullProgramMemory(&g_fsProgramMemory))
{
LOG_MSG_ERROR("Failed to retrieve full FS program memory dump!");
return false;
}
/* Look for the initial data block in the FS memory dump using the package ID and the initial data hash from the gamecard header. */
for(u64 offset = 0; offset < g_fsProgramMemory.data_size; offset++)
{
if ((g_fsProgramMemory.data_size - offset) < sizeof(GameCardInitialData)) break;
if (memcmp(g_fsProgramMemory.data + offset, g_gameCardHeader.package_id, sizeof(g_gameCardHeader.package_id)) != 0) continue;
sha256CalculateHash(tmp_hash, g_fsProgramMemory.data + offset, sizeof(GameCardInitialData));
if (!memcmp(tmp_hash, g_gameCardHeader.initial_data_hash, SHA256_HASH_SIZE))
{
/* Jackpot. */
memcpy(out, g_fsProgramMemory.data + offset + sizeof(GameCardInitialData) - sizeof(GameCardSecurityInformation), sizeof(GameCardSecurityInformation));
/* Clear out the current ASIC session hash. */
/* It's not actually part of the gamecard data, and this changes every time a gamecard (re)insertion takes place. */
memset(out->specific_data.asic_session_hash, 0xFF, sizeof(out->specific_data.asic_session_hash));
found = true;
break;
}
}
/* Free FS memory dump. */
memFreeMemoryLocation(&g_fsProgramMemory);
return found;
}
static bool gamecardGetHandleAndStorage(u32 partition)
{
if (g_gameCardStatus < GameCardStatus_InsertedAndInfoNotLoaded || partition > 1)
{
LOG_MSG_ERROR("Invalid parameters!");
return false;
}
Result rc = 0;
/* 10 tries. */
for(u8 i = 0; i < 10; i++)
{
/* 100 ms wait in case there was an error in the previous loop. */
if (R_FAILED(rc)) svcSleepThread(100000000);
/* First, let's try to retrieve a gamecard handle. */
/* This can return an error if the "nogc" patch is enabled by the running CFW (most commonly 0x140A02). */
rc = fsDeviceOperatorGetGameCardHandle(&g_deviceOperator, &g_gameCardHandle);
if (R_FAILED(rc))
{
LOG_MSG_DEBUG("fsDeviceOperatorGetGameCardHandle failed on try #%u! (0x%X).", i + 1, rc);
continue;
}
/* If the previous call succeeded, let's try to open the desired gamecard storage area. */
rc = fsOpenGameCardStorage(&g_gameCardStorage, &g_gameCardHandle, partition);
if (R_FAILED(rc))
{
gamecardCloseHandle(); /* Close invalid gamecard handle. */
LOG_MSG_DEBUG("fsOpenGameCardStorage failed to open %s storage area on try #%u! (0x%X).", GAMECARD_STORAGE_AREA_NAME(partition + 1), i + 1, rc);
continue;
}
/* If we got up to this point, both a valid gamecard handle and a valid storage area handle are guaranteed. */
break;
}
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsDeviceOperatorGetGameCardHandle / fsOpenGameCardStorage failed! (0x%X).", rc);
if (g_gameCardStatus == GameCardStatus_InsertedAndInfoNotLoaded && partition == 0) g_gameCardStatus = GameCardStatus_NoGameCardPatchEnabled;
}
return R_SUCCEEDED(rc);
}
NX_INLINE void gamecardCloseHandle(void)
{
g_gameCardHandle.value = 0;
}
static bool gamecardOpenStorageArea(u8 area)
{
if (g_gameCardStatus < GameCardStatus_InsertedAndInfoNotLoaded || (area != GameCardStorageArea_Normal && area != GameCardStorageArea_Secure))
{
LOG_MSG_ERROR("Invalid parameters!");
return false;
}
/* Return right away if a valid handle has already been retrieved and the desired gamecard storage area is currently open. */
if (g_gameCardHandle.value && serviceIsActive(&(g_gameCardStorage.s)) && g_gameCardCurrentStorageArea == area) return true;
/* Close both gamecard handle and open storage area. */
gamecardCloseStorageArea();
/* Retrieve both a new gamecard handle and a storage area handle. */
if (!gamecardGetHandleAndStorage(area - 1)) /* Zero-based index. */
{
LOG_MSG_ERROR("Failed to retrieve gamecard handle and storage area handle! (%s).", GAMECARD_STORAGE_AREA_NAME(area));
return false;
}
/* Update current gamecard storage area. */
g_gameCardCurrentStorageArea = area;
return true;
}
static bool gamecardReadStorageArea(void *out, u64 read_size, u64 offset)
{
if (g_gameCardStatus < GameCardStatus_InsertedAndInfoNotLoaded || !g_gameCardNormalAreaSize || !g_gameCardSecureAreaSize || !out || !read_size || (offset + read_size) > g_gameCardTotalSize)
{
LOG_MSG_ERROR("Invalid parameters!");
return false;
}
Result rc = 0;
u8 *out_u8 = (u8*)out;
u8 area = (offset < g_gameCardNormalAreaSize ? GameCardStorageArea_Normal : GameCardStorageArea_Secure);
bool success = false;
/* Handle reads that span both the normal and secure gamecard storage areas. */
if (area == GameCardStorageArea_Normal && (offset + read_size) > g_gameCardNormalAreaSize)
{
/* Calculate normal storage area size difference. */
u64 diff_size = (g_gameCardNormalAreaSize - offset);
/* Read normal storage area data. */
if (!gamecardReadStorageArea(out_u8, diff_size, offset)) goto end;
/* Adjust variables to read right from the start of the secure storage area. */
read_size -= diff_size;
offset = g_gameCardNormalAreaSize;
out_u8 += diff_size;
area = GameCardStorageArea_Secure;
}
/* Open a storage area if needed. */
/* If the right storage area has already been opened, this will return true. */
if (!gamecardOpenStorageArea(area))
{
LOG_MSG_ERROR("Failed to open %s storage area!", GAMECARD_STORAGE_AREA_NAME(area));
goto end;
}
/* Calculate proper storage area offset. */
u64 base_offset = (area == GameCardStorageArea_Normal ? offset : (offset - g_gameCardNormalAreaSize));
if (!(base_offset % GAMECARD_PAGE_SIZE) && !(read_size % GAMECARD_PAGE_SIZE))
{
/* Optimization for reads that are already aligned to a GAMECARD_PAGE_SIZE boundary. */
rc = fsStorageRead(&g_gameCardStorage, base_offset, out_u8, read_size);
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsStorageRead failed to read 0x%lX bytes at offset 0x%lX from %s storage area! (0x%X) (aligned).", read_size, base_offset, GAMECARD_STORAGE_AREA_NAME(area), rc);
goto end;
}
success = true;
} else {
/* Fix offset and/or size to avoid unaligned reads. */
u64 block_start_offset = ALIGN_DOWN(base_offset, GAMECARD_PAGE_SIZE);
u64 block_end_offset = ALIGN_UP(base_offset + read_size, GAMECARD_PAGE_SIZE);
u64 block_size = (block_end_offset - block_start_offset);
u64 data_start_offset = (base_offset - block_start_offset);
u64 chunk_size = (block_size > GAMECARD_READ_BUFFER_SIZE ? GAMECARD_READ_BUFFER_SIZE : block_size);
u64 out_chunk_size = (block_size > GAMECARD_READ_BUFFER_SIZE ? (GAMECARD_READ_BUFFER_SIZE - data_start_offset) : read_size);
rc = fsStorageRead(&g_gameCardStorage, block_start_offset, g_gameCardReadBuf, chunk_size);
if (R_FAILED(rc))
{
LOG_MSG_ERROR("fsStorageRead failed to read 0x%lX bytes at offset 0x%lX from %s storage area! (0x%X) (unaligned).", chunk_size, block_start_offset, GAMECARD_STORAGE_AREA_NAME(area), rc);
goto end;
}
memcpy(out_u8, g_gameCardReadBuf + data_start_offset, out_chunk_size);
success = (block_size > GAMECARD_READ_BUFFER_SIZE ? gamecardReadStorageArea(out_u8 + out_chunk_size, read_size - out_chunk_size, offset + out_chunk_size) : true);
}
end:
return success;
}
static void gamecardCloseStorageArea(void)
{
if (g_gameCardCurrentStorageArea == GameCardStorageArea_None) return;
if (serviceIsActive(&(g_gameCardStorage.s)))
{
fsStorageClose(&g_gameCardStorage);
memset(&g_gameCardStorage, 0, sizeof(FsStorage));
}
gamecardCloseHandle();
g_gameCardCurrentStorageArea = GameCardStorageArea_None;
}
static bool gamecardGetStorageAreasSizes(void)
{
for(u8 i = 0; i < 2; i++)
{
Result rc = 0;
u64 area_size = 0;
u8 area = (i == 0 ? GameCardStorageArea_Normal : GameCardStorageArea_Secure);
if (!gamecardOpenStorageArea(area))
{
LOG_MSG_ERROR("Failed to open %s storage area!", GAMECARD_STORAGE_AREA_NAME(area));
return false;
}
rc = fsStorageGetSize(&g_gameCardStorage, (s64*)&area_size);
gamecardCloseStorageArea();
if (R_FAILED(rc) || !area_size)
{
LOG_MSG_ERROR("fsStorageGetSize failed to retrieve %s storage area size! (0x%X).", GAMECARD_STORAGE_AREA_NAME(area), rc);
return false;
}
if (area == GameCardStorageArea_Normal)
{
g_gameCardNormalAreaSize = area_size;
} else {
g_gameCardSecureAreaSize = area_size;
}
}
g_gameCardTotalSize = (g_gameCardNormalAreaSize + g_gameCardSecureAreaSize);
return true;
}
NX_INLINE u64 gamecardGetCapacityFromRomSizeValue(u8 rom_size)
{
u64 capacity = 0;
switch(rom_size)
{
case GameCardRomSize_1GiB:
capacity = GameCardCapacity_1GiB;
break;
case GameCardRomSize_2GiB:
capacity = GameCardCapacity_2GiB;
break;
case GameCardRomSize_4GiB:
capacity = GameCardCapacity_4GiB;
break;
case GameCardRomSize_8GiB:
capacity = GameCardCapacity_8GiB;
break;
case GameCardRomSize_16GiB:
capacity = GameCardCapacity_16GiB;
break;
case GameCardRomSize_32GiB:
capacity = GameCardCapacity_32GiB;
break;
default:
break;
}
return capacity;
}
static HashFileSystemContext *gamecardInitializeHashFileSystemContext(const char *name, u64 offset, u64 size, u8 *hash, u64 hash_target_offset, u32 hash_target_size)
{
u32 i = 0, magic = 0;
HashFileSystemContext *hfs_ctx = NULL;
HashFileSystemHeader hfs_header = {0};
u8 hfs_header_hash[SHA256_HASH_SIZE] = {0};
bool success = false, dump_fs_header = false;
if ((name && !*name) || offset < (GAMECARD_CERTIFICATE_OFFSET + sizeof(FsGameCardCertificate)) || !IS_ALIGNED(offset, GAMECARD_PAGE_SIZE) || \
(size && (!IS_ALIGNED(size, GAMECARD_PAGE_SIZE) || (offset + size) > g_gameCardTotalSize)))
{
LOG_MSG_ERROR("Invalid parameters!");
goto end;
}
/* Allocate memory for the output context. */
hfs_ctx = calloc(1, sizeof(HashFileSystemContext));
if (!hfs_ctx)
{
LOG_MSG_ERROR("Unable to allocate memory for Hash FS context! (offset 0x%lX).", offset);
goto end;
}
/* Duplicate partition name. */
hfs_ctx->name = (name ? strdup(name) : strdup(hfsGetPartitionNameString(HashFileSystemPartitionType_Root)));
if (!hfs_ctx->name)
{
LOG_MSG_ERROR("Failed to duplicate Hash FS partition name! (offset 0x%lX).", offset);
goto end;
}
/* Determine Hash FS partition type. */
for(i = HashFileSystemPartitionType_Root; i < HashFileSystemPartitionType_Count; i++)
{
const char *hfs_partition_name = hfsGetPartitionNameString((u8)i);
if (hfs_partition_name && !strcmp(hfs_partition_name, hfs_ctx->name)) break;
}
if (i >= HashFileSystemPartitionType_Count)
{
LOG_MSG_ERROR("Failed to find a matching Hash FS partition type for \"%s\"! (offset 0x%lX).", hfs_ctx->name, offset);
goto end;
}
hfs_ctx->type = i;
/* Read partial Hash FS header. */
if (!gamecardReadStorageArea(&hfs_header, sizeof(HashFileSystemHeader), offset))
{
LOG_MSG_ERROR("Failed to read partial Hash FS header! (\"%s\", offset 0x%lX).", hfs_ctx->name, offset);
goto end;
}
magic = __builtin_bswap32(hfs_header.magic);
if (magic != HFS0_MAGIC)
{
LOG_MSG_ERROR("Invalid Hash FS magic word! (0x%08X) (\"%s\", offset 0x%lX).", magic, hfs_ctx->name, offset);
dump_fs_header = true;
goto end;
}
/* Check Hash FS entry count and name table size. */
/* Only allow a zero entry count if we're not dealing with the root partition. Never allow a zero-sized name table. */
if ((!name && !hfs_header.entry_count) || !hfs_header.name_table_size)
{
LOG_MSG_ERROR("Invalid Hash FS entry count / name table size! (\"%s\", offset 0x%lX).", hfs_ctx->name, offset);
dump_fs_header = true;
goto end;
}
/* Calculate full Hash FS header size. */
hfs_ctx->header_size = (sizeof(HashFileSystemHeader) + (hfs_header.entry_count * sizeof(HashFileSystemEntry)) + hfs_header.name_table_size);
hfs_ctx->header_size = ALIGN_UP(hfs_ctx->header_size, GAMECARD_PAGE_SIZE);
/* Allocate memory for the full Hash FS header. */
hfs_ctx->header = calloc(hfs_ctx->header_size, sizeof(u8));
if (!hfs_ctx->header)
{
LOG_MSG_ERROR("Unable to allocate 0x%lX bytes buffer for the full Hash FS header! (\"%s\", offset 0x%lX).", hfs_ctx->header_size, hfs_ctx->name, offset);
goto end;
}
/* Read full Hash FS header. */
if (!gamecardReadStorageArea(hfs_ctx->header, hfs_ctx->header_size, offset))
{
LOG_MSG_ERROR("Failed to read full Hash FS header! (\"%s\", offset 0x%lX).", hfs_ctx->name, offset);
goto end;
}
/* Verify Hash FS header (if possible). */
if (hash && hash_target_size && (hash_target_offset + hash_target_size) <= hfs_ctx->header_size)
{
sha256CalculateHash(hfs_header_hash, hfs_ctx->header + hash_target_offset, hash_target_size);
if (memcmp(hfs_header_hash, hash, SHA256_HASH_SIZE) != 0)
{
LOG_MSG_ERROR("Hash FS header doesn't match expected SHA-256 hash! (\"%s\", offset 0x%lX).", hfs_ctx->name, offset);
goto end;
}
}
/* Fill context. */
hfs_ctx->offset = offset;
if (name)
{
/* Use provided partition size. */
hfs_ctx->size = size;
} else {
/* Calculate root partition size. */
HashFileSystemEntry *hfs_entry = hfsGetEntryByIndex(hfs_ctx, hfs_header.entry_count - 1);
hfs_ctx->size = (hfs_ctx->header_size + hfs_entry->offset + hfs_entry->size);
}
/* Update flag. */
success = true;
end:
if (!success && hfs_ctx)
{
if (dump_fs_header) LOG_DATA_DEBUG(&hfs_header, sizeof(HashFileSystemHeader), "Partial Hash FS header dump (\"%s\", offset 0x%lX):", hfs_ctx->name, offset);
if (hfs_ctx->header) free(hfs_ctx->header);
if (hfs_ctx->name) free(hfs_ctx->name);
free(hfs_ctx);
hfs_ctx = NULL;
}
return hfs_ctx;
}
static HashFileSystemContext *_gamecardGetHashFileSystemContext(u8 hfs_partition_type)
{
HashFileSystemContext *hfs_ctx = NULL;
if (!g_gameCardInterfaceInit || g_gameCardStatus != GameCardStatus_InsertedAndInfoLoaded || !g_gameCardHfsCount || !g_gameCardHfsCtx || \
hfs_partition_type < HashFileSystemPartitionType_Root || hfs_partition_type >= HashFileSystemPartitionType_Count)
{
LOG_MSG_ERROR("Invalid parameters!");
goto end;
}
/* Return right away if the root partition was requested. */
if (hfs_partition_type == HashFileSystemPartitionType_Root)
{
hfs_ctx = g_gameCardHfsCtx[0];
goto end;
}
/* Try to find the requested partition by looping through our Hash FS contexts. */
for(u32 i = 1; i < g_gameCardHfsCount; i++)
{
hfs_ctx = g_gameCardHfsCtx[i];
if (hfs_ctx->type == hfs_partition_type) break;
hfs_ctx = NULL;
}
if (!hfs_ctx) LOG_MSG_ERROR("Failed to locate Hash FS partition with type %u!", hfs_partition_type);
end:
return hfs_ctx;
}