HBLInstallerWrapper/source/function_patcher.cpp

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#include <cstring>
#include <coreinit/cache.h>
#include <coreinit/dynload.h>
#include <coreinit/memorymap.h>
#include <coreinit/debug.h>
#include "utils/logger.h"
#include "../patches/src/function_patching.h"
#include "elfio/elfio.hpp"
#include "setup_syscalls.h"
using namespace ELFIO;
bool isDynamicFunction(uint32_t physicalAddress) {
if ((physicalAddress & 0x80000000) == 0x80000000) {
return true;
}
return false;
}
rpl_handling rpl_handles[] __attribute__((section(".data"))) = {
{LIBRARY_AVM, "avm.rpl", nullptr},
{LIBRARY_CAMERA, "camera.rpl", nullptr},
{LIBRARY_COREINIT, "coreinit.rpl", nullptr},
{LIBRARY_DC, "dc.rpl", nullptr},
{LIBRARY_DMAE, "dmae.rpl", nullptr},
{LIBRARY_DRMAPP, "drmapp.rpl", nullptr},
{LIBRARY_ERREULA, "erreula.rpl", nullptr},
{LIBRARY_GX2, "gx2.rpl", nullptr},
{LIBRARY_H264, "h264.rpl", nullptr},
{LIBRARY_LZMA920, "lzma920.rpl", nullptr},
{LIBRARY_MIC, "mic.rpl", nullptr},
{LIBRARY_NFC, "nfc.rpl", nullptr},
{LIBRARY_NIO_PROF, "nio_prof.rpl", nullptr},
{LIBRARY_NLIBCURL, "nlibcurl.rpl", nullptr},
{LIBRARY_NLIBNSS, "nlibnss.rpl", nullptr},
{LIBRARY_NLIBNSS2, "nlibnss2.rpl", nullptr},
{LIBRARY_NN_AC, "nn_ac.rpl", nullptr},
{LIBRARY_NN_ACP, "nn_acp.rpl", nullptr},
{LIBRARY_NN_ACT, "nn_act.rpl", nullptr},
{LIBRARY_NN_AOC, "nn_aoc.rpl", nullptr},
{LIBRARY_NN_BOSS, "nn_boss.rpl", nullptr},
{LIBRARY_NN_CCR, "nn_ccr.rpl", nullptr},
{LIBRARY_NN_CMPT, "nn_cmpt.rpl", nullptr},
{LIBRARY_NN_DLP, "nn_dlp.rpl", nullptr},
{LIBRARY_NN_EC, "nn_ec.rpl", nullptr},
{LIBRARY_NN_FP, "nn_fp.rpl", nullptr},
{LIBRARY_NN_HAI, "nn_hai.rpl", nullptr},
{LIBRARY_NN_HPAD, "nn_hpad.rpl", nullptr},
{LIBRARY_NN_IDBE, "nn_idbe.rpl", nullptr},
{LIBRARY_NN_NDM, "nn_ndm.rpl", nullptr},
{LIBRARY_NN_NETS2, "nn_nets2.rpl", nullptr},
{LIBRARY_NN_NFP, "nn_nfp.rpl", nullptr},
{LIBRARY_NN_NIM, "nn_nim.rpl", nullptr},
{LIBRARY_NN_OLV, "nn_olv.rpl", nullptr},
{LIBRARY_NN_PDM, "nn_pdm.rpl", nullptr},
{LIBRARY_NN_SAVE, "nn_save.rpl", nullptr},
{LIBRARY_NN_SL, "nn_sl.rpl", nullptr},
{LIBRARY_NN_SPM, "nn_spm.rpl", nullptr},
{LIBRARY_NN_TEMP, "nn_temp.rpl", nullptr},
{LIBRARY_NN_UDS, "nn_uds.rpl", nullptr},
{LIBRARY_NN_VCTL, "nn_vctl.rpl", nullptr},
{LIBRARY_NSYSCCR, "nsysccr.rpl", nullptr},
{LIBRARY_NSYSHID, "nsyshid.rpl", nullptr},
{LIBRARY_NSYSKBD, "nsyskbd.rpl", nullptr},
{LIBRARY_NSYSNET, "nsysnet.rpl", nullptr},
{LIBRARY_NSYSUHS, "nsysuhs.rpl", nullptr},
{LIBRARY_NSYSUVD, "nsysuvd.rpl", nullptr},
{LIBRARY_NTAG, "ntag.rpl", nullptr},
{LIBRARY_PADSCORE, "padscore.rpl", nullptr},
{LIBRARY_PROC_UI, "proc_ui.rpl", nullptr},
{LIBRARY_SNDCORE2, "sndcore2.rpl", nullptr},
{LIBRARY_SNDUSER2, "snduser2.rpl", nullptr},
{LIBRARY_SND_CORE, "snd_core.rpl", nullptr},
{LIBRARY_SND_USER, "snd_user.rpl", nullptr},
{LIBRARY_SWKBD, "swkbd.rpl", nullptr},
{LIBRARY_SYSAPP, "sysapp.rpl", nullptr},
{LIBRARY_TCL, "tcl.rpl", nullptr},
{LIBRARY_TVE, "tve.rpl", nullptr},
{LIBRARY_UAC, "uac.rpl", nullptr},
{LIBRARY_UAC_RPL, "uac_rpl.rpl", nullptr},
{LIBRARY_USB_MIC, "usb_mic.rpl", nullptr},
{LIBRARY_UVC, "uvc.rpl", nullptr},
{LIBRARY_UVD, "uvd.rpl", nullptr},
{LIBRARY_VPAD, "vpad.rpl", nullptr},
{LIBRARY_VPADBASE, "vpadbase.rpl", nullptr},
{LIBRARY_ZLIB125, "zlib125.rpl", nullptr}
};
uint32_t getAddressOfFunction(const char *functionName, library_type_t library) {
uint32_t real_addr = 0;
OSDynLoad_Module rpl_handle = nullptr;
OSDynLoad_Error err = OS_DYNLOAD_OK;
int32_t rpl_handles_size = sizeof rpl_handles / sizeof rpl_handles[0];
for (int32_t i = 0; i < rpl_handles_size; i++) {
if (rpl_handles[i].library == library) {
if (rpl_handles[i].handle == nullptr) {
//DEBUG_FUNCTION_LINE("Lets acquire handle for rpl: %s", rpl_handles[i].rplname);
err = OSDynLoad_IsModuleLoaded((char *) rpl_handles[i].rplname, &rpl_handles[i].handle);
}
if (err != OS_DYNLOAD_OK || !rpl_handles[i].handle) {
WHBLogWritef("%s failed to acquire %d %08X\n", rpl_handles[i].rplname, err, rpl_handles[i].handle);
return 0;
}
rpl_handle = rpl_handles[i].handle;
break;
}
}
if (!rpl_handle) {
DEBUG_FUNCTION_LINE("Failed to find the RPL handle for %s", functionName);
return 0;
}
OSDynLoad_FindExport(rpl_handle, 0, functionName, reinterpret_cast<void **>(&real_addr));
if (!real_addr) {
DEBUG_FUNCTION_LINE("OSDynLoad_FindExport failed for %s", functionName);
return 0;
}
if ((library == LIBRARY_NN_ACP) && (uint32_t) (*(volatile uint32_t *) (real_addr) & 0x48000002) == 0x48000000) {
auto address_diff = (uint32_t) (*(volatile uint32_t *) (real_addr) & 0x03FFFFFC);
if ((address_diff & 0x03000000) == 0x03000000) {
address_diff |= 0xFC000000;
}
real_addr += (int32_t) address_diff;
if ((uint32_t) (*(volatile uint32_t *) (real_addr) & 0x48000002) == 0x48000000) {
return 0;
}
}
return real_addr;
}
void PatchFunction(function_patcher_entry_t *function_data) {
if (function_data->_function.isAlreadyPatched) {
DEBUG_FUNCTION_LINE("%s is already patch, we can skip it", function_data->_function.name);
return;
}
/* Patch branches to it. */
volatile uint32_t *space = function_data->_function.replace_data;
DEBUG_FUNCTION_LINE_VERBOSE("Patching %s ...", function_data->_function.name);
auto physical = (uint32_t) function_data->_function.physical_address;
auto repl_addr = (uint32_t) function_data->_function.target;
auto call_addr = (uint32_t) function_data->_function.call_addr;
auto real_addr = (uint32_t) function_data->_function.virtual_address;
if (function_data->_function.library != LIBRARY_OTHER) {
real_addr = getAddressOfFunction(function_data->_function.name, function_data->_function.library);
}
if (!real_addr) {
WHBLogWritef("");
DEBUG_FUNCTION_LINE("OSDynLoad_FindExport failed for %s", function_data->_function.name);
return;
}
DEBUG_FUNCTION_LINE_VERBOSE("%s is located at %08X!", function_data->_function.name, real_addr);
if (function_data->_function.library != LIBRARY_OTHER) {
physical = (uint32_t) OSEffectiveToPhysical(real_addr);
}
if (!physical) {
WHBLogWritef("Error. Something is wrong with the physical address");
return;
}
DEBUG_FUNCTION_LINE_VERBOSE("%s physical is located at %08X!", function_data->_function.name, physical);
*(volatile uint32_t *) (call_addr) = (uint32_t) (space);
auto targetAddr = (uint32_t) space;
if (targetAddr < 0x00800000 || targetAddr >= 0x01000000) {
targetAddr = (uint32_t) OSEffectiveToPhysical(targetAddr);
} else {
targetAddr = targetAddr + 0x30800000 - 0x00800000;
}
SC_0x25_KernelCopyData(targetAddr, physical, 4);
ICInvalidateRange((void *) (space), 4);
DCFlushRange((void *) (space), 4);
space++;
uint32_t restoreInstruction = space[-1];
/*
00808cfc 3d601234 lis r11 ,0x1234
00808d00 616b5678 ori r11 ,r11 ,0x5678
00808d04 7d6903a6 mtspr CTR ,r11
00808d08 4e800420 bctr
*/
*space = 0x3d600000 | (((real_addr + 4) >> 16) & 0x0000FFFF);
space++; // lis r11 ,0x1234
*space = 0x616b0000 | ((real_addr + 4) & 0x0000ffff);
space++; // ori r11 ,r11 ,0x5678
*space = 0x7d6903a6;
space++; // mtspr CTR ,r11
*space = 0x4e800420;
space++; // bctr
//setting jump back
uint32_t replace_instr = 0x48000002 | (repl_addr & 0x03FFFFFC);
// If the jump is too big or we want only patch for certain processes we need a trampoline
if (repl_addr > 0x03FFFFFC || function_data->_function.targetProcess != TARGET_PROCESS_ALL) {
auto repl_addr_test = (uint32_t) space;
if (function_data->_function.targetProcess != TARGET_PROCESS_ALL) {
// Only use patched function if OSGetUPID matches function_data->targetProcess
*space = 0x3d600000 | (((uint32_t *) OSGetUPID)[0] & 0x0000FFFF);
space++; // lis r11 ,0x0
*space = 0x816b0000 | (((uint32_t *) OSGetUPID)[1] & 0x0000FFFF);
space++; // lwz r11 ,0x0(r11)
if (function_data->_function.targetProcess == TARGET_PROCESS_GAME_AND_MENU) {
*space = 0x2c0b0000 | TARGET_PROCESS_WII_U_MENU;
space++; // cmpwi r11 ,WUPS_FP_TARGET_PROCESS_WII_U_MENU
*space = 0x41820000 | 0x00000020;
space++; // beq myfunc
*space = 0x2c0b0000 | TARGET_PROCESS_GAME;
space++; // cmpwi r11 ,FP_TARGET_PROCESS_GAME
*space = 0x41820000 | 0x00000018;
space++; // beq myfunc
} else {
*space = 0x2c0b0000 | function_data->_function.targetProcess;
space++; // cmpwi r11 ,function_data->targetProcess
*space = 0x41820000 | 0x00000018;
space++; // beq myfunc
}
*space = 0x3d600000 | (((real_addr + 4) >> 16) & 0x0000FFFF);
space++; // lis r11 ,(real_addr + 4)@hi
*space = 0x616b0000 | ((real_addr + 4) & 0x0000ffff);
space++; // ori r11 ,(real_addr + 4)@lo
*space = 0x7d6903a6;
space++; // mtspr CTR ,r11
*space = restoreInstruction;
space++; //
*space = 0x4e800420;
space++; // bctr
}
// myfunc:
*space = 0x3d600000 | (((repl_addr) >> 16) & 0x0000FFFF);
space++; // lis r11 ,repl_addr@hi
*space = 0x616b0000 | ((repl_addr) & 0x0000ffff);
space++; // ori r11 ,r11 ,repl_addr@lo
*space = 0x7d6903a6;
space++; // mtspr CTR ,r11
*space = 0x4e800420;
space++; // bctr
// Make sure the trampoline itself is usable.
if ((repl_addr_test & 0x03FFFFFC) != repl_addr_test) {
DEBUG_FUNCTION_LINE("%08X != %08X", (repl_addr_test & 0x03FFFFFC), repl_addr_test);
OSFatal("Jump is impossible");
}
replace_instr = 0x48000002 | (repl_addr_test & 0x03FFFFFC);
}
if (space > &function_data->_function.replace_data[FUNCTION_PATCHER_METHOD_STORE_SIZE]) {
OSFatal("The replacement data is too long.");
}
DEBUG_FUNCTION_LINE_VERBOSE("Write instruction %08X to %08X [%08X] on core %d", replace_instr, real_addr, physical, OSGetThreadAffinity(OSGetCurrentThread()) / 2);
uint32_t replace_instruction = replace_instr;
uint32_t physical_address = physical;
uint32_t effective_address = real_addr;
DCFlushRange(&replace_instruction, 4);
DCFlushRange(&physical_address, 4);
auto replace_instruction_physical = (uint32_t) &replace_instruction;
if (replace_instruction_physical < 0x00800000 || replace_instruction_physical >= 0x01000000) {
replace_instruction_physical = OSEffectiveToPhysical(replace_instruction_physical);
} else {
replace_instruction_physical = replace_instruction_physical + 0x30800000 - 0x00800000;
}
SC_0x25_KernelCopyData(physical_address, replace_instruction_physical, 4);
ICInvalidateRange((void *) (effective_address), 4);
if (!isDynamicFunction(physical)) {
DEBUG_FUNCTION_LINE("Set isAlreadyPatched = true");
function_data->_function.isAlreadyPatched = true;
}
}