/* * Copyright (c) 2018 Atmosphère-NX * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. * * This program is distributed in the hope 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 . */ #include #include #include #include #include "sha256.h" #include "lz4.h" #include "ldr_nso.hpp" #include "ldr_map.hpp" #include "ldr_random.hpp" #include "ldr_patcher.hpp" static NsoUtils::NsoHeader g_nso_headers[NSO_NUM_MAX] = {0}; static bool g_nso_present[NSO_NUM_MAX] = {0}; static char g_nso_path[FS_MAX_PATH] = {0}; FILE *NsoUtils::OpenNsoFromExeFS(unsigned int index) { std::fill(g_nso_path, g_nso_path + FS_MAX_PATH, 0); snprintf(g_nso_path, FS_MAX_PATH, "code:/%s", NsoUtils::GetNsoFileName(index)); return fopen(g_nso_path, "rb"); } FILE *NsoUtils::OpenNsoFromSdCard(unsigned int index, u64 title_id) { std::fill(g_nso_path, g_nso_path + FS_MAX_PATH, 0); snprintf(g_nso_path, FS_MAX_PATH, "sdmc:/atmosphere/titles/%016lx/exefs/%s", title_id, NsoUtils::GetNsoFileName(index)); return fopen(g_nso_path, "rb"); } bool NsoUtils::CheckNsoStubbed(unsigned int index, u64 title_id) { std::fill(g_nso_path, g_nso_path + FS_MAX_PATH, 0); snprintf(g_nso_path, FS_MAX_PATH, "sdmc:/atmosphere/titles/%016lx/exefs/%s.stub", title_id, NsoUtils::GetNsoFileName(index)); FILE *f = fopen(g_nso_path, "rb"); bool ret = (f != NULL); if (ret) { fclose(f); } return ret; } FILE *NsoUtils::OpenNso(unsigned int index, u64 title_id) { FILE *f_out = OpenNsoFromSdCard(index, title_id); if (f_out != NULL) { return f_out; } else if (CheckNsoStubbed(index, title_id)) { return NULL; } else { return OpenNsoFromExeFS(index); } } bool NsoUtils::IsNsoPresent(unsigned int index) { return g_nso_present[index]; } unsigned char *NsoUtils::GetNsoBuildId(unsigned int index) { if (g_nso_present[index]) { return g_nso_headers[index].build_id; } return NULL; } Result NsoUtils::LoadNsoHeaders(u64 title_id) { FILE *f_nso; /* Zero out the cache. */ std::fill(g_nso_present, g_nso_present + NSO_NUM_MAX, false); std::fill(g_nso_headers, g_nso_headers + NSO_NUM_MAX, (const NsoUtils::NsoHeader &){0}); for (unsigned int i = 0; i < NSO_NUM_MAX; i++) { f_nso = OpenNso(i, title_id); if (f_nso != NULL) { if (fread(&g_nso_headers[i], 1, sizeof(NsoUtils::NsoHeader), f_nso) != sizeof(NsoUtils::NsoHeader)) { return 0xA09; } g_nso_present[i] = true; fclose(f_nso); f_nso = NULL; continue; } if (1 < i && i < 12) { /* If we failed to open a subsdk, there are no more subsdks. */ i = 11; } } return 0x0; } Result NsoUtils::ValidateNsoLoadSet() { /* We *must* have a "main" NSO. */ if (!g_nso_present[1]) { return 0xA09; } /* Behavior switches depending on whether we have an rtld. */ if (g_nso_present[0]) { /* If we have an rtld, dst offset for .text must be 0 for all other NSOs. */ for (unsigned int i = 0; i < NSO_NUM_MAX; i++) { if (g_nso_present[i] && g_nso_headers[i].segments[0].dst_offset != 0) { return 0xA09; } } } else { /* If we don't have an rtld, we must ONLY have a main. */ for (unsigned int i = 2; i < NSO_NUM_MAX; i++) { if (g_nso_present[i]) { return 0xA09; } } /* That main's .text must be at dst_offset 0. */ if (g_nso_headers[1].segments[0].dst_offset != 0) { return 0xA09; } } return 0x0; } Result NsoUtils::CalculateNsoLoadExtents(u32 addspace_type, u32 args_size, NsoLoadExtents *extents) { *extents = (const NsoUtils::NsoLoadExtents){0}; /* Calculate base offsets. */ for (unsigned int i = 0; i < NSO_NUM_MAX; i++) { if (g_nso_present[i]) { extents->nso_addresses[i] = extents->total_size; u32 text_end = g_nso_headers[i].segments[0].dst_offset + g_nso_headers[i].segments[0].decomp_size; u32 ro_end = g_nso_headers[i].segments[1].dst_offset + g_nso_headers[i].segments[1].decomp_size; u32 rw_end = g_nso_headers[i].segments[2].dst_offset + g_nso_headers[i].segments[2].decomp_size + g_nso_headers[i].segments[2].align_or_total_size; extents->nso_sizes[i] = text_end; if (extents->nso_sizes[i] < ro_end) { extents->nso_sizes[i] = ro_end; } if (extents->nso_sizes[i] < rw_end) { extents->nso_sizes[i] = rw_end; } extents->nso_sizes[i] += 0xFFF; extents->nso_sizes[i] &= ~0xFFFULL; extents->total_size += extents->nso_sizes[i]; if (args_size && !extents->args_size) { extents->args_address = extents->total_size; /* What the fuck? Where does 0x9007 come from? */ extents->args_size = (2 * args_size + 0x9007); extents->args_size &= ~0xFFFULL; extents->total_size += extents->args_size; } } } /* Calculate ASLR extents for address space type. */ u64 addspace_start, addspace_size; if (kernelAbove200()) { switch (addspace_type & 0xE) { case 0: case 4: addspace_start = 0x200000ULL; addspace_size = 0x3FE00000ULL; break; case 2: addspace_start = 0x8000000ULL; addspace_size = 0x78000000ULL; break; case 6: addspace_start = 0x8000000ULL; addspace_size = 0x7FF8000000ULL; break; default: /* TODO: Panic. */ return 0xD001; } } else { if (addspace_type & 2) { addspace_start = 0x8000000ULL; addspace_size = 0x78000000ULL; } else { addspace_start = 0x200000ULL; addspace_size = 0x3FE00000ULL; } } if (extents->total_size > addspace_size) { return 0xD001; } u64 aslr_slide = 0; if (addspace_type & 0x20) { aslr_slide = RandomUtils::GetRandomU64((addspace_size - extents->total_size) >> 21) << 21; } extents->base_address = addspace_start + aslr_slide; for (unsigned int i = 0; i < NSO_NUM_MAX; i++) { if (g_nso_present[i]) { extents->nso_addresses[i] += extents->base_address; } } if (extents->args_address) { extents->args_address += extents->base_address; } return 0x0; } Result NsoUtils::LoadNsoSegment(u64 title_id, unsigned int index, unsigned int segment, FILE *f_nso, u8 *map_base, u8 *map_end) { bool is_compressed = ((g_nso_headers[index].flags >> segment) & 1) != 0; bool check_hash = ((g_nso_headers[index].flags >> (segment + 3)) & 1) != 0; size_t out_size = g_nso_headers[index].segments[segment].decomp_size; size_t size = is_compressed ? g_nso_headers[index].compressed_sizes[segment] : out_size; if (size > out_size) { return 0xA09; } if ((u32)(size | out_size) >> 31) { return 0xA09; } u8 *dst_addr = map_base + g_nso_headers[index].segments[segment].dst_offset; u8 *load_addr = is_compressed ? map_end - size : dst_addr; fseek(f_nso, g_nso_headers[index].segments[segment].file_offset, SEEK_SET); if (fread(load_addr, 1, size, f_nso) != size) { return 0xA09; } if (is_compressed) { if (LZ4_decompress_safe((char *)load_addr, (char *)dst_addr, size, out_size) != (int)out_size) { return 0xA09; } } if (check_hash) { u8 hash[0x20] = {0}; struct sha256_state sha_ctx; sha256_init(&sha_ctx); sha256_update(&sha_ctx, dst_addr, out_size); sha256_finalize(&sha_ctx); sha256_finish(&sha_ctx, hash); if (std::memcmp(g_nso_headers[index].section_hashes[segment], hash, sizeof(hash))) { return 0xA09; } } return 0x0; } Result NsoUtils::LoadNsosIntoProcessMemory(Handle process_h, u64 title_id, NsoLoadExtents *extents, u8 *args, u32 args_size) { Result rc = 0xA09; for (unsigned int i = 0; i < NSO_NUM_MAX; i++) { if (g_nso_present[i]) { AutoCloseMap nso_map; if (R_FAILED((rc = nso_map.Open(process_h, extents->nso_addresses[i], extents->nso_sizes[i])))) { return rc; } u8 *map_base = (u8 *)nso_map.GetMappedAddress(); FILE *f_nso = OpenNso(i, title_id); if (f_nso == NULL) { /* Is there a better error to return here? */ return 0xA09; } for (unsigned int seg = 0; seg < 3; seg++) { if (R_FAILED((rc = LoadNsoSegment(title_id, i, seg, f_nso, map_base, map_base + extents->nso_sizes[i])))) { fclose(f_nso); return rc; } } fclose(f_nso); f_nso = NULL; /* Zero out memory before .text. */ u64 text_base = 0, text_start = g_nso_headers[i].segments[0].dst_offset; std::fill(map_base + text_base, map_base + text_start, 0); /* Zero out memory before .rodata. */ u64 ro_base = text_start + g_nso_headers[i].segments[0].decomp_size, ro_start = g_nso_headers[i].segments[1].dst_offset; std::fill(map_base + ro_base, map_base + ro_start, 0); /* Zero out memory before .rwdata. */ u64 rw_base = ro_start + g_nso_headers[i].segments[1].decomp_size, rw_start = g_nso_headers[i].segments[2].dst_offset; std::fill(map_base + rw_base, map_base + rw_start, 0); /* Zero out .bss. */ u64 bss_base = rw_start + g_nso_headers[i].segments[2].decomp_size, bss_size = g_nso_headers[i].segments[2].align_or_total_size; std::fill(map_base + bss_base, map_base + bss_base + bss_size, 0); /* Apply patches to loaded module. */ PatchUtils::ApplyPatches(&g_nso_headers[i], map_base, bss_base); nso_map.Close(); for (unsigned int seg = 0; seg < 3; seg++) { u64 size = g_nso_headers[i].segments[seg].decomp_size; if (seg == 2) { size += g_nso_headers[i].segments[2].align_or_total_size; } size += 0xFFF; size &= ~0xFFFULL; const static unsigned int segment_perms[3] = {5, 1, 3}; if (R_FAILED((rc = svcSetProcessMemoryPermission(process_h, extents->nso_addresses[i] + g_nso_headers[i].segments[seg].dst_offset, size, segment_perms[seg])))) { return rc; } } } } /* Map in arguments. */ if (args != NULL && args_size) { AutoCloseMap args_map; if (R_FAILED((rc = args_map.Open(process_h, extents->args_address, extents->args_size)))) { return rc; } NsoArgument *arg_map_base = (NsoArgument *)args_map.GetMappedAddress(); arg_map_base->allocated_space = extents->args_size; arg_map_base->args_size = args_size; std::fill(arg_map_base->_0x8, arg_map_base->_0x8 + sizeof(arg_map_base->_0x8), 0); std::copy(args, args + args_size, arg_map_base->arguments); args_map.Close(); if (R_FAILED((rc = svcSetProcessMemoryPermission(process_h, extents->args_address, extents->args_size, 3)))) { return rc; } } return rc; }