/* * This file is part of Luma3DS * Copyright (C) 2016-2018 Aurora Wright, TuxSH * * This program 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. * * This program 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 . * * Additional Terms 7.b and 7.c of GPLv3 apply to this file: * * Requiring preservation of specified reasonable legal notices or * author attributions in that material or in the Appropriate Legal * Notices displayed by works containing it. * * Prohibiting misrepresentation of the origin of that material, * or requiring that modified versions of such material be marked in * reasonable ways as different from the original version. */ /* This file was entirely written by fincs */ #include <3ds.h> #include "3dsx.h" #include "memory.h" #define Log_PrintP(...) ((void)0) #define MAXRELOCS 512 static _3DSX_Reloc s_relocBuf[MAXRELOCS]; u32 ldrArgvBuf[ARGVBUF_SIZE/4]; #define SEC_ASSERT(x) do { if (!(x)) { Log_PrintP("Assertion failed: %s", #x); return false; } } while (0) typedef struct { void* segPtrs[3]; // code, rodata & data u32 segAddrs[3]; u32 segSizes[3]; } _3DSX_LoadInfo; static inline u32 TranslateAddr(u32 off, _3DSX_LoadInfo* d, u32* offsets) { if (off < offsets[0]) return d->segAddrs[0] + off; if (off < offsets[1]) return d->segAddrs[1] + off - offsets[0]; return d->segAddrs[2] + off - offsets[1]; } u32 IFile_Read2(IFile *file, void* buffer, u32 size, u32 offset) { Result res; u64 total = 0; file->pos = offset; res = IFile_Read(file, &total, buffer, size); return R_SUCCEEDED(res) ? total : 0; } bool Ldr_Get3dsxSize(u32* pSize, IFile *file) { _3DSX_Header hdr; if (IFile_Read2(file, &hdr, sizeof(hdr), 0) != sizeof(hdr)) { Log_PrintP("Cannot read 3DSX header"); return false; } if (hdr.magic != _3DSX_MAGIC) { Log_PrintP("Not a valid 3DSX file"); return false; } u32 segSizes[3]; segSizes[0] = (hdr.codeSegSize+0xFFF) &~ 0xFFF; segSizes[1] = (hdr.rodataSegSize+0xFFF) &~ 0xFFF; segSizes[2] = (hdr.dataSegSize+0xFFF) &~ 0xFFF; SEC_ASSERT(segSizes[0] >= hdr.codeSegSize); SEC_ASSERT(segSizes[1] >= hdr.rodataSegSize); SEC_ASSERT(segSizes[2] >= hdr.dataSegSize); // TODO: Check int overflow *pSize = segSizes[0] + segSizes[1] + segSizes[2] + 0x1000; // One extra page reserved for settings/etc return true; } static inline u32 min(u32 a, u32 b) { return a < b ? a : b; } Handle Ldr_CodesetFrom3dsx(const char* name, u32* codePages, u32 baseAddr, IFile *file, u64 tid) { u32 i,j,k,m; Result res; _3DSX_Header hdr; IFile_Read2(file, &hdr, sizeof(hdr), 0); _3DSX_LoadInfo d; d.segSizes[0] = (hdr.codeSegSize+0xFFF) &~ 0xFFF; d.segSizes[1] = (hdr.rodataSegSize+0xFFF) &~ 0xFFF; d.segSizes[2] = (hdr.dataSegSize+0xFFF) &~ 0xFFF; d.segPtrs[0] = codePages; d.segPtrs[1] = (char*)d.segPtrs[0] + d.segSizes[0]; d.segPtrs[2] = (char*)d.segPtrs[1] + d.segSizes[1]; d.segAddrs[0] = baseAddr; d.segAddrs[1] = d.segAddrs[0] + d.segSizes[0]; d.segAddrs[2] = d.segAddrs[1] + d.segSizes[1]; u32 offsets[2] = { d.segSizes[0], d.segSizes[0] + d.segSizes[1] }; u32* segLimit = d.segPtrs[2] + d.segSizes[2]; u32 readOffset = hdr.headerSize; u32 nRelocTables = hdr.relocHdrSize/4; SEC_ASSERT((3*4*nRelocTables) <= 0x1000); u32* extraPage = (u32*)((char*)d.segPtrs[2] + d.segSizes[2]); u32 extraPageAddr = d.segAddrs[2] + d.segSizes[2]; // Read the relocation headers for (i = 0; i < 3; i ++) { if (IFile_Read2(file, &extraPage[i*nRelocTables], hdr.relocHdrSize, readOffset) != hdr.relocHdrSize) { Log_PrintP("Cannot read relheader %d", i); return 0; } readOffset += hdr.relocHdrSize; } // Read the code segment if (IFile_Read2(file, d.segPtrs[0], hdr.codeSegSize, readOffset) != hdr.codeSegSize) { Log_PrintP("Cannot read code segment"); return 0; } readOffset += hdr.codeSegSize; // Read the rodata segment if (IFile_Read2(file, d.segPtrs[1], hdr.rodataSegSize, readOffset) != hdr.rodataSegSize) { Log_PrintP("Cannot read rodata segment"); return 0; } readOffset += hdr.rodataSegSize; // Read the data segment u32 dataLoadSegSize = hdr.dataSegSize - hdr.bssSize; if (IFile_Read2(file, d.segPtrs[2], dataLoadSegSize, readOffset) != dataLoadSegSize) { Log_PrintP("Cannot read data segment"); return 0; } readOffset += dataLoadSegSize; // Relocate the segments for (i = 0; i < 3; i ++) { for (j = 0; j < nRelocTables; j ++) { int nRelocs = extraPage[i*nRelocTables + j]; if (j >= (sizeof(_3DSX_RelocHdr)/4)) { // Not using this header readOffset += nRelocs; continue; } u32* pos = (u32*)d.segPtrs[i]; u32* endPos = pos + (d.segSizes[i]/4); SEC_ASSERT(endPos <= segLimit); while (nRelocs) { u32 toDo = nRelocs > MAXRELOCS ? MAXRELOCS : nRelocs; nRelocs -= toDo; u32 readSize = toDo*sizeof(_3DSX_Reloc); if (IFile_Read2(file, s_relocBuf, readSize, readOffset) != readSize) { Log_PrintP("Cannot read reloc table (%d,%d)", i, j); return 0; } readOffset += readSize; for (k = 0; k < toDo && pos < endPos; k ++) { pos += s_relocBuf[k].skip; u32 nPatches = s_relocBuf[k].patch; for (m = 0; m < nPatches && pos < endPos; m ++) { u32 inAddr = baseAddr + 4*(pos - codePages); u32 origData = *pos; u32 subType = origData >> (32-4); u32 addr = TranslateAddr(origData &~ 0xF0000000, &d, offsets); //Log_PrintP("%08lX<-%08lX", inAddr, addr); switch (j) { case 0: { if (subType != 0) { Log_PrintP("Unsupported absolute reloc subtype (%lu)", subType); return 0; } *pos = addr; break; } case 1: { u32 data = addr - inAddr; switch (subType) { case 0: *pos = data; break; // 32-bit signed offset case 1: *pos = data &~ BIT(31); break; // 31-bit signed offset default: Log_PrintP("Unsupported relative reloc subtype (%lu)", subType); return 0; } break; } } pos++; } } } } } // Detect and fill _prm structure PrmStruct* pst = (PrmStruct*) &codePages[1]; if (pst->magic == _PRM_MAGIC) { memset(extraPage, 0, 0x1000); memcpy(extraPage, ldrArgvBuf, sizeof(ldrArgvBuf)); pst->pSrvOverride = extraPageAddr + 0xFFC; pst->pArgList = extraPageAddr; pst->runFlags |= RUNFLAG_APTCHAINLOAD; s64 dummy; bool isN3DS = svcGetSystemInfo(&dummy, 0x10001, 0) == 0; if (isN3DS) { pst->heapSize = 48*1024*1024; pst->linearHeapSize = 64*1024*1024; } else { pst->heapSize = 24*1024*1024; pst->linearHeapSize = 32*1024*1024; } } // Create the codeset CodeSetInfo csinfo; memset(&csinfo, 0, sizeof(csinfo)); strncpy((char*)csinfo.name, name, 8); csinfo.program_id = tid; csinfo.text_addr = d.segAddrs[0]; csinfo.text_size = d.segSizes[0] >> 12; csinfo.ro_addr = d.segAddrs[1]; csinfo.ro_size = d.segSizes[1] >> 12; csinfo.rw_addr = d.segAddrs[2]; csinfo.rw_size = (d.segSizes[2] >> 12) + 1; // One extra page reserved for settings/etc csinfo.text_size_total = csinfo.text_size; csinfo.ro_size_total = csinfo.ro_size; csinfo.rw_size_total = csinfo.rw_size; Handle hCodeset = 0; res = svcCreateCodeSet(&hCodeset, &csinfo, d.segPtrs[0], d.segPtrs[1], d.segPtrs[2]); if (res) { Log_PrintP("svcCreateCodeSet: %08lX", res); return 0; } return hCodeset; }