/* * firm.c */ #include "firm.h" #include "config.h" #include "utils.h" #include "fs.h" #include "patches.h" #include "memory.h" #include "emunand.h" #include "crypto.h" #include "exceptions.h" #include "draw.h" #include "screeninit.h" #include "buttons.h" #include "../build/patches.h" static firmHeader *const firm = (firmHeader *)0x24000000; static const firmSectionHeader *section; u32 config, console, firmSource, emuOffset; void main(void) { u32 bootType, firmType, nandType, a9lhMode, updatedSys, needConfig, newConfig, emuHeader; //Detect the console being used console = PDN_MPCORE_CFG == 7; //Mount filesystems. CTRNAND will be mounted only if/when needed mountFs(); const char configPath[] = "/luma/config.bin"; //Attempt to read the configuration file needConfig = fileRead(&config, configPath) ? 1 : 2; //Determine if this is a firmlaunch boot if(*(vu8 *)0x23F00005) { if(needConfig == 2) mcuReboot(); bootType = 1; //'0' = NATIVE_FIRM, '1' = TWL_FIRM, '2' = AGB_FIRM firmType = *(vu8 *)0x23F00009 == '3' ? 3 : *(vu8 *)0x23F00005 - '0'; nandType = BOOTCONFIG(0, 3); firmSource = BOOTCONFIG(2, 1); a9lhMode = BOOTCONFIG(3, 1); updatedSys = a9lhMode && CONFIG(1); } else { //Get pressed buttons u32 pressed = HID_PAD; //If no configuration file exists or SELECT is held, load configuration menu if(needConfig == 2 || (pressed & BUTTON_SELECT)) configureCFW(configPath); u32 devMode = CONFIG(5); if(devMode) detectAndProcessExceptionDumps(); bootType = 0; firmType = 0; //Determine if booting with A9LH u32 a9lhBoot = !PDN_SPI_CNT; //Determine if A9LH is installed and the user has an updated sysNAND if(a9lhBoot || CONFIG(2)) { a9lhMode = 1; updatedSys = CONFIG(1); } else { a9lhMode = 0; updatedSys = 0; } newConfig = a9lhMode << 3; if(a9lhBoot) { //Retrieve the last booted FIRM u32 previousFirm = CFG_BOOTENV; //If it's a MCU reboot, try to force boot options if(previousFirm) { //Always force a sysNAND boot when quitting AGB_FIRM if(previousFirm == 7) { nandType = 0; firmSource = updatedSys ? 0 : BOOTCONFIG(2, 1); needConfig--; //Flag to prevent multiple boot options-forcing newConfig |= 1 << 4; } /* Else, force the last used boot options unless a payload button or A/L/R are pressed or the no-forcing flag is set */ else if(!(pressed & OVERRIDE_BUTTONS) && !BOOTCONFIG(4, 1)) { nandType = BOOTCONFIG(0, 3); firmSource = BOOTCONFIG(2, 1); needConfig--; } } //If the SAFE MODE combo is held, force a sysNAND boot else if(pressed == SAFE_MODE) { a9lhMode++; nandType = 0; firmSource = 0; needConfig--; } } //Boot options aren't being forced if(needConfig) { /* If L and R/A/Select or one of the single payload buttons are pressed, chainload an external payload */ if(devMode || (pressed & SINGLE_PAYLOAD_BUTTONS) || ((pressed & BUTTON_L1) && (pressed & L_PAYLOAD_BUTTONS))) loadPayload(pressed, devMode); //If screens are inited or the corresponding option is set, load splash screen if(PDN_GPU_CNT != 1 || CONFIG(8)) loadSplash(); //If R is pressed, boot the non-updated NAND with the FIRM of the opposite one if(pressed & BUTTON_R1) { nandType = updatedSys; firmSource = !nandType; } /* Else, boot the NAND the user set to autoboot or the opposite one, depending on L, with their own FIRM */ else { nandType = CONFIG(0) != !(pressed & BUTTON_L1); firmSource = nandType; } /* If we're booting emuNAND the second emuNAND is set as default and B isn't pressed, or vice-versa, boot the second emuNAND */ if(nandType && (CONFIG(3) == !(pressed & BUTTON_B))) nandType++; } } //If we need to boot emuNAND, make sure it exists if(nandType) { getEmunandSect(&emuOffset, &emuHeader, &nandType); if(!nandType) firmSource = 0; } //Same if we're using emuNAND as the FIRM source else if(firmSource) getEmunandSect(&emuOffset, &emuHeader, &firmSource); if(!bootType) { newConfig |= nandType | (firmSource << 2); /* If the boot configuration is different from previously, overwrite it. Just the no-forcing flag being set is not enough */ if((newConfig & 0x2F) != (config & 0x3F)) { //Preserve user settings (last 26 bits) newConfig |= config & 0xFFFFFFC0; fileWrite(&newConfig, configPath, 4); } } loadFirm(firmType, !firmType && updatedSys == !firmSource); switch(firmType) { case 0: patchNativeFirm(nandType, emuHeader, a9lhMode); break; case 3: patchSafeFirm(); break; default: patchLegacyFirm(firmType); break; } launchFirm(bootType); } static inline void loadFirm(u32 firmType, u32 externalFirm) { section = firm->section; u32 externalFirmLoaded = externalFirm && fileRead(firm, "/luma/firmware.bin") && (((u32)section[2].address >> 8) & 0xFF) == (console ? 0x60 : 0x68); /* If the conditions to load the external FIRM aren't met, or reading fails, or the FIRM doesn't match the console, load FIRM from CTRNAND */ if(!externalFirmLoaded) { const char *firmFolders[4][2] = {{ "00000002", "20000002" }, { "00000102", "20000102" }, { "00000202", "20000202" }, { "00000003", "20000003" }}; firmRead(firm, firmFolders[firmType][console]); decryptExeFs((u8 *)firm); } } static inline void patchNativeFirm(u32 nandType, u32 emuHeader, u32 a9lhMode) { u8 *arm9Section = (u8 *)firm + section[2].offset; u32 nativeFirmType; if(console) { //Determine if we're booting the 9.0 FIRM nativeFirmType = arm9Section[0x51] != 0xFF; //Decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader arm9Loader(arm9Section, nativeFirmType); firm->arm9Entry = (u8 *)0x801B01C; } else { //Determine if we're booting the 9.0 FIRM u8 firm90Hash[0x10] = {0x27, 0x2D, 0xFE, 0xEB, 0xAF, 0x3F, 0x6B, 0x3B, 0xF5, 0xDE, 0x4C, 0x41, 0xDE, 0x95, 0x27, 0x6A}; nativeFirmType = memcmp(section[2].hash, firm90Hash, 0x10) != 0; } if(nativeFirmType || nandType || a9lhMode == 2) { //Find the Process9 NCCH location u8 *proc9Offset = getProc9(arm9Section, section[2].size); //Apply emuNAND patches if(nandType) patchEmuNAND(arm9Section, proc9Offset, emuHeader); //Apply FIRM reboot patches, not on 9.0 FIRM as it breaks firmlaunchhax if(nativeFirmType || a9lhMode == 2) patchReboots(arm9Section, proc9Offset); } //Apply FIRM0/1 writes patches on sysNAND to protect A9LH if(a9lhMode && !nandType) patchFirmWrites(arm9Section, 1); //Apply signature checks patches u32 sigOffset, sigOffset2; getSigChecks(arm9Section, section[2].size, &sigOffset, &sigOffset2); *(u16 *)sigOffset = sigPatch[0]; *(u16 *)sigOffset2 = sigPatch[0]; *((u16 *)sigOffset2 + 1) = sigPatch[1]; if(CONFIG(5)) { //Apply UNITINFO patch u8 *unitInfoOffset = getUnitInfoValueSet(arm9Section, section[2].size); *unitInfoOffset = unitInfoPatch; } //Replace the FIRM loader with the injector injectLoader(); } static inline void patchEmuNAND(u8 *arm9Section, u8 *proc9Offset, u32 emuHeader) { //Copy emuNAND code void *emuCodeOffset = getEmuCode(proc9Offset); memcpy(emuCodeOffset, emunand, emunand_size); //Add the data of the found emuNAND u32 *pos_offset = (u32 *)memsearch(emuCodeOffset, "NAND", emunand_size, 4); u32 *pos_header = (u32 *)memsearch(emuCodeOffset, "NCSD", emunand_size, 4); *pos_offset = emuOffset; *pos_header = emuHeader; //Find and add the SDMMC struct u32 *pos_sdmmc = (u32 *)memsearch(emuCodeOffset, "SDMC", emunand_size, 4); *pos_sdmmc = getSDMMC(arm9Section, section[2].size); //Calculate offset for the hooks u32 branchOffset = (u32)emuCodeOffset - (u32)firm - section[2].offset + (u32)section[2].address; //Add emuNAND hooks u32 emuRead, emuWrite; getEmuRW(arm9Section, section[2].size, &emuRead, &emuWrite); *(u16 *)emuRead = nandRedir[0]; *((u16 *)emuRead + 1) = nandRedir[1]; *((u32 *)emuRead + 1) = branchOffset; *(u16 *)emuWrite = nandRedir[0]; *((u16 *)emuWrite + 1) = nandRedir[1]; *((u32 *)emuWrite + 1) = branchOffset; //Set MPU for emu code region u32 *mpuOffset = getMPU(arm9Section, section[2].size); *mpuOffset = mpuPatch[0]; *(mpuOffset + 6) = mpuPatch[1]; *(mpuOffset + 9) = mpuPatch[2]; } static inline void patchReboots(u8 *arm9Section, u8 *proc9Offset) { //Calculate offset for the firmlaunch code void *rebootOffset = getReboot(arm9Section, section[2].size); //Calculate offset for the fOpen function u32 fOpenOffset = getfOpen(proc9Offset, rebootOffset); //Copy firmlaunch code memcpy(rebootOffset, reboot, reboot_size); //Put the fOpen offset in the right location u32 *pos_fopen = (u32 *)memsearch(rebootOffset, "OPEN", reboot_size, 4); *pos_fopen = fOpenOffset; } static inline void injectLoader(void) { u32 loaderSize; void *loaderOffset = getLoader((u8 *)firm + section[0].offset, section[0].size, &loaderSize); //Check that the injector CXI isn't larger than the original if((u32)injector_size <= loaderSize) { memcpy(loaderOffset, injector, injector_size); //Patch content size and ExeFS size to match the repaced loader's ones *((u32 *)loaderOffset + 0x41) = loaderSize / 0x200; *((u32 *)loaderOffset + 0x69) = loaderSize / 0x200 - 5; } } static inline void patchLegacyFirm(u32 firmType) { //On N3DS, decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader if(console) { arm9Loader((u8 *)firm + section[3].offset, 0); firm->arm9Entry = (u8 *)0x801301C; } const patchData twlPatches[] = { {{0x1650C0, 0x165D64}, {{ 6, 0x00, 0x20, 0x4E, 0xB0, 0x70, 0xBD }}, 0}, {{0x173A0E, 0x17474A}, { .type1 = 0x2001 }, 1}, {{0x174802, 0x17553E}, { .type1 = 0x2000 }, 2}, {{0x174964, 0x1756A0}, { .type1 = 0x2000 }, 2}, {{0x174D52, 0x175A8E}, { .type1 = 0x2001 }, 2}, {{0x174D5E, 0x175A9A}, { .type1 = 0x2001 }, 2}, {{0x174D6A, 0x175AA6}, { .type1 = 0x2001 }, 2}, {{0x174E56, 0x175B92}, { .type1 = 0x2001 }, 1}, {{0x174E58, 0x175B94}, { .type1 = 0x4770 }, 1} }, agbPatches[] = { {{0x9D2A8, 0x9DF64}, {{ 6, 0x00, 0x20, 0x4E, 0xB0, 0x70, 0xBD }}, 0}, {{0xD7A12, 0xD8B8A}, { .type1 = 0xEF26 }, 1} }; /* Calculate the amount of patches to apply. Only count the boot screen patch for AGB_FIRM if the matching option was enabled (keep it as last) */ u32 numPatches = firmType == 1 ? (sizeof(twlPatches) / sizeof(patchData)) : (sizeof(agbPatches) / sizeof(patchData) - !CONFIG(7)); const patchData *patches = firmType == 1 ? twlPatches : agbPatches; //Patch for(u32 i = 0; i < numPatches; i++) { switch(patches[i].type) { case 0: memcpy((u8 *)firm + patches[i].offset[console], patches[i].patch.type0 + 1, patches[i].patch.type0[0]); break; case 2: *(u16 *)((u8 *)firm + patches[i].offset[console] + 2) = 0; case 1: *(u16 *)((u8 *)firm + patches[i].offset[console]) = patches[i].patch.type1; break; } } } static inline void patchSafeFirm(void) { u8 *arm9Section = (u8 *)firm + section[2].offset; if(console) { //Decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader arm9Loader(arm9Section, 0); firm->arm9Entry = (u8 *)0x801B01C; } //Apply FIRM0/1 writes patches to protect A9LH patchFirmWrites(arm9Section, console); } static void patchFirmWrites(u8 *arm9Section, u32 mode) { if(mode) { u16 *writeOffset = getFirmWrite(arm9Section, section[2].size); *writeOffset = writeBlock[0]; *(writeOffset + 1) = writeBlock[1]; } else { u16 *writeOffset = getFirmWriteSafe(arm9Section, section[2].size); *writeOffset = writeBlockSafe[0]; *(writeOffset + 1) = writeBlockSafe[1]; } } static inline void launchFirm(u32 bootType) { //Copy FIRM sections to respective memory locations for(u32 i = 0; i < 4 && section[i].size; i++) memcpy(section[i].address, (u8 *)firm + section[i].offset, section[i].size); //Determine the ARM11 entry to use vu32 *arm11; if(bootType) arm11 = (u32 *)0x1FFFFFFC; else { deinitScreens(); arm11 = (u32 *)0x1FFFFFF8; } //Set ARM11 kernel entrypoint *arm11 = (u32)firm->arm11Entry; //Final jump to ARM9 kernel ((void (*)())firm->arm9Entry)(); }