/* * This file is part of the TREZOR project. * * Copyright (C) 2014 Pavol Rusnak * * This library is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This library 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 Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with this library. If not, see . */ #include #include #include #include "messages.pb.h" #include "storage.pb.h" #include "trezor.h" #include "sha2.h" #include "aes.h" #include "pbkdf2.h" #include "bip32.h" #include "bip39.h" #include "curves.h" #include "util.h" #include "memory.h" #include "rng.h" #include "storage.h" #include "debug.h" #include "protect.h" #include "layout2.h" Storage storage; uint8_t storage_uuid[12]; char storage_uuid_str[25]; /* storage layout: offset | type/length | description --------+--------------+------------------------------- 0x0000 | 4 bytes | magic = 'stor' 0x0004 | 12 bytes | uuid 0x0010 | ? bytes | Storage structure --------+--------------+------------------------------- 0x4000 | 4 kbytes | area for pin failures 0x5000 | 256 bytes | area for u2f counter updates 0x5100 | 11.75 kbytes | reserved The area for pin failures looks like this: 0 ... 0 pinfail 0xffffffff .. 0xffffffff The pinfail is a binary number of the form 1...10...0, the number of zeros is the number of pin failures. This layout is used because we can only clear bits without erasing the flash. The area for u2f counter updates is just a sequence of zero-bits followed by a sequence of one-bits. The bits in a byte are numbered from LSB to MSB. The number of zero bits is the offset that should be added to the storage u2f_counter to get the real counter value. */ #define FLASH_STORAGE_PINAREA (FLASH_META_START + 0x4000) #define FLASH_STORAGE_PINAREA_LEN (0x1000) #define FLASH_STORAGE_U2FAREA (FLASH_STORAGE_PINAREA + FLASH_STORAGE_PINAREA_LEN) #define FLASH_STORAGE_U2FAREA_LEN (0x100) #define FLASH_STORAGE_REALLEN (4 + sizeof(storage_uuid) + sizeof(Storage)) _Static_assert(FLASH_STORAGE_START + FLASH_STORAGE_REALLEN <= FLASH_STORAGE_PINAREA, "Storage struct is too large for TREZOR flash"); _Static_assert((sizeof(storage_uuid) & 3) == 0, "storage uuid unaligned"); _Static_assert((sizeof(storage) & 3) == 0, "storage unaligned"); /* Current u2f offset, i.e. u2f counter is * storage.u2f_counter + storage_u2f_offset. * This corresponds to the number of cleared bits in the U2FAREA. */ static uint32_t storage_u2f_offset; static bool sessionSeedCached, sessionSeedUsesPassphrase; static uint8_t sessionSeed[64]; static bool sessionPinCached; static bool sessionPassphraseCached; static char sessionPassphrase[51]; #define STORAGE_VERSION 6 void storage_check_flash_errors(void) { // flash operation failed if (FLASH_SR & (FLASH_SR_PGAERR | FLASH_SR_PGPERR | FLASH_SR_PGSERR | FLASH_SR_WRPERR)) { layoutDialog(DIALOG_ICON_ERROR, NULL, NULL, NULL, "Storage failure", "detected.", NULL, "Please unplug", "the device.", NULL); for (;;) { } } } bool storage_from_flash(void) { if (memcmp((void *)FLASH_STORAGE_START, "stor", 4) != 0) { // wrong magic return false; } uint32_t version = ((Storage *)(FLASH_STORAGE_START + 4 + sizeof(storage_uuid)))->version; // version 1: since 1.0.0 // version 2: since 1.2.1 // version 3: since 1.3.1 // version 4: since 1.3.2 // version 5: since 1.3.3 // version 6: since 1.3.6 if (version > STORAGE_VERSION) { // downgrade -> clear storage return false; } // load uuid memcpy(storage_uuid, (void *)(FLASH_STORAGE_START + 4), sizeof(storage_uuid)); data2hex(storage_uuid, sizeof(storage_uuid), storage_uuid_str); // copy storage memcpy(&storage, (void *)(FLASH_STORAGE_START + 4 + sizeof(storage_uuid)), sizeof(Storage)); if (version <= 5) { // convert PIN failure counter from version 5 format uint32_t pinctr = storage.has_pin_failed_attempts ? storage.pin_failed_attempts : 0; if (pinctr > 31) pinctr = 31; flash_clear_status_flags(); flash_unlock(); // erase extra storage sector flash_erase_sector(FLASH_META_SECTOR_LAST, FLASH_CR_PROGRAM_X32); flash_program_word(FLASH_STORAGE_PINAREA, 0xffffffff << pinctr); flash_lock(); storage_check_flash_errors(); storage.has_pin_failed_attempts = false; storage.pin_failed_attempts = 0; } uint32_t *u2fptr = (uint32_t*) FLASH_STORAGE_U2FAREA; while (*u2fptr == 0) u2fptr++; storage_u2f_offset = 32 * (u2fptr - (uint32_t*) FLASH_STORAGE_U2FAREA); uint32_t u2fword = *u2fptr; while ((u2fword & 1) == 0) { storage_u2f_offset++; u2fword >>= 1; } // upgrade storage version if (version != STORAGE_VERSION) { storage.version = STORAGE_VERSION; storage_commit(); } return true; } void storage_init(void) { if (!storage_from_flash()) { storage_reset(); storage_reset_uuid(); storage_commit(); storage_clearPinArea(); } } void storage_reset_uuid(void) { // set random uuid random_buffer(storage_uuid, sizeof(storage_uuid)); data2hex(storage_uuid, sizeof(storage_uuid), storage_uuid_str); } void storage_reset(void) { // reset storage struct memset(&storage, 0, sizeof(storage)); storage.version = STORAGE_VERSION; session_clear(true); // clear PIN as well } void session_clear(bool clear_pin) { sessionSeedCached = false; memset(&sessionSeed, 0, sizeof(sessionSeed)); sessionPassphraseCached = false; memset(&sessionPassphrase, 0, sizeof(sessionPassphrase)); if (clear_pin) { sessionPinCached = false; } } static uint32_t storage_flash_words(uint32_t addr, uint32_t *src, int nwords) { int i; for (i = 0; i < nwords; i++) { flash_program_word(addr, *src++); addr += 4; } return addr; } static void storage_commit_locked(void) { uint8_t meta_backup[FLASH_META_DESC_LEN]; // backup meta memcpy(meta_backup, (uint8_t*)FLASH_META_START, FLASH_META_DESC_LEN); // erase storage flash_erase_sector(FLASH_META_SECTOR_FIRST, FLASH_CR_PROGRAM_X32); // copy meta uint32_t flash = FLASH_META_START; flash = storage_flash_words(flash, (uint32_t *)meta_backup, FLASH_META_DESC_LEN/4); // copy storage flash_program_word(flash, *(uint32_t *) "stor"); flash += 4; flash = storage_flash_words(flash, (uint32_t *)&storage_uuid, sizeof(storage_uuid)/4); flash = storage_flash_words(flash, (uint32_t *)&storage, sizeof(storage)/4); // fill remainder with zero for future extensions while (flash < FLASH_STORAGE_PINAREA) { flash_program_word(flash, 0); flash += 4; } } void storage_commit(void) { flash_clear_status_flags(); flash_unlock(); storage_commit_locked(); flash_lock(); storage_check_flash_errors(); } void storage_loadDevice(LoadDevice *msg) { storage_reset(); storage.has_imported = true; storage.imported = true; if (msg->has_pin > 0) { storage_setPin(msg->pin); } if (msg->has_passphrase_protection) { storage.has_passphrase_protection = true; storage.passphrase_protection = msg->passphrase_protection; } else { storage.has_passphrase_protection = false; } if (msg->has_node) { storage.has_node = true; storage.has_mnemonic = false; memcpy(&storage.node, &(msg->node), sizeof(HDNodeType)); sessionSeedCached = false; memset(&sessionSeed, 0, sizeof(sessionSeed)); } else if (msg->has_mnemonic) { storage.has_mnemonic = true; storage.has_node = false; strlcpy(storage.mnemonic, msg->mnemonic, sizeof(storage.mnemonic)); sessionSeedCached = false; memset(&sessionSeed, 0, sizeof(sessionSeed)); } if (msg->has_language) { storage_setLanguage(msg->language); } if (msg->has_label) { storage_setLabel(msg->label); } } void storage_setLabel(const char *label) { if (!label) return; storage.has_label = true; strlcpy(storage.label, label, sizeof(storage.label)); } void storage_setLanguage(const char *lang) { if (!lang) return; // sanity check if (strcmp(lang, "english") == 0) { storage.has_language = true; strlcpy(storage.language, lang, sizeof(storage.language)); } } void storage_setPassphraseProtection(bool passphrase_protection) { sessionSeedCached = false; sessionPassphraseCached = false; storage.has_passphrase_protection = true; storage.passphrase_protection = passphrase_protection; } void storage_setHomescreen(const uint8_t *data, uint32_t size) { if (data && size == 1024) { storage.has_homescreen = true; memcpy(storage.homescreen.bytes, data, size); storage.homescreen.size = size; } else { storage.has_homescreen = false; memset(storage.homescreen.bytes, 0, sizeof(storage.homescreen.bytes)); storage.homescreen.size = 0; } } void get_root_node_callback(uint32_t iter, uint32_t total) { layoutProgress("Waking up", 1000 * iter / total); } const uint8_t *storage_getSeed(bool usePassphrase) { // root node is properly cached if (usePassphrase == sessionSeedUsesPassphrase && sessionSeedCached) { return sessionSeed; } // if storage has mnemonic, convert it to node and use it if (storage.has_mnemonic) { if (usePassphrase && !protectPassphrase()) { return NULL; } mnemonic_to_seed(storage.mnemonic, usePassphrase ? sessionPassphrase : "", sessionSeed, get_root_node_callback); // BIP-0039 sessionSeedCached = true; sessionSeedUsesPassphrase = usePassphrase; return sessionSeed; } return NULL; } bool storage_getRootNode(HDNode *node, const char *curve, bool usePassphrase) { // if storage has node, decrypt and use it if (storage.has_node && strcmp(curve, SECP256K1_NAME) == 0) { if (!protectPassphrase()) { return false; } if (hdnode_from_xprv(storage.node.depth, storage.node.fingerprint, storage.node.child_num, storage.node.chain_code.bytes, storage.node.private_key.bytes, curve, node) == 0) { return false; } if (storage.has_passphrase_protection && storage.passphrase_protection && sessionPassphraseCached && strlen(sessionPassphrase) > 0) { // decrypt hd node uint8_t secret[64]; PBKDF2_HMAC_SHA512_CTX pctx; pbkdf2_hmac_sha512_Init(&pctx, (const uint8_t *)sessionPassphrase, strlen(sessionPassphrase), (const uint8_t *)"TREZORHD", 8); get_root_node_callback(0, BIP39_PBKDF2_ROUNDS); for (int i = 0; i < 8; i++) { pbkdf2_hmac_sha512_Update(&pctx, BIP39_PBKDF2_ROUNDS / 8); get_root_node_callback((i + 1) * BIP39_PBKDF2_ROUNDS / 8, BIP39_PBKDF2_ROUNDS); } pbkdf2_hmac_sha512_Final(&pctx, secret); aes_decrypt_ctx ctx; aes_decrypt_key256(secret, &ctx); aes_cbc_decrypt(node->chain_code, node->chain_code, 32, secret + 32, &ctx); aes_cbc_decrypt(node->private_key, node->private_key, 32, secret + 32, &ctx); } return true; } const uint8_t *seed = storage_getSeed(usePassphrase); if (seed == NULL) { return false; } return hdnode_from_seed(seed, 64, curve, node); } const char *storage_getLabel(void) { return storage.has_label ? storage.label : 0; } const char *storage_getLanguage(void) { return storage.has_language ? storage.language : 0; } const uint8_t *storage_getHomescreen(void) { return (storage.has_homescreen && storage.homescreen.size == 1024) ? storage.homescreen.bytes : 0; } /* Check whether pin matches storage. The pin must be a null-terminated * string with at most 9 characters. */ bool storage_isPinCorrect(const char *pin) { /* The execution time of the following code only depends on the * (public) input. This avoids timing attacks. */ char diff = 0; uint32_t i = 0; while (pin[i]) { diff |= storage.pin[i] - pin[i]; i++; } diff |= storage.pin[i]; return diff == 0; } bool storage_hasPin(void) { return storage.has_pin && storage.pin[0] != 0; } void storage_setPin(const char *pin) { if (pin && pin[0]) { storage.has_pin = true; strlcpy(storage.pin, pin, sizeof(storage.pin)); } else { storage.has_pin = false; storage.pin[0] = 0; } storage_commit(); sessionPinCached = false; } void session_cachePassphrase(const char *passphrase) { strlcpy(sessionPassphrase, passphrase, sizeof(sessionPassphrase)); sessionPassphraseCached = true; } bool session_isPassphraseCached(void) { return sessionPassphraseCached; } void session_cachePin(void) { sessionPinCached = true; } bool session_isPinCached(void) { return sessionPinCached; } void storage_clearPinArea(void) { flash_clear_status_flags(); flash_unlock(); flash_erase_sector(FLASH_META_SECTOR_LAST, FLASH_CR_PROGRAM_X32); flash_lock(); storage_check_flash_errors(); storage_u2f_offset = 0; } // called when u2f area or pin area overflows static void storage_area_recycle(uint32_t new_pinfails) { // erase storage sector flash_erase_sector(FLASH_META_SECTOR_LAST, FLASH_CR_PROGRAM_X32); flash_program_word(FLASH_STORAGE_PINAREA, new_pinfails); if (storage_u2f_offset > 0) { storage.has_u2f_counter = true; storage.u2f_counter += storage_u2f_offset; storage_commit_locked(); storage_u2f_offset = 0; } } void storage_resetPinFails(uint32_t *pinfailsptr) { flash_clear_status_flags(); flash_unlock(); if ((uint32_t) (pinfailsptr + 1) >= FLASH_STORAGE_PINAREA + FLASH_STORAGE_PINAREA_LEN) { // recycle extra storage sector storage_area_recycle(0xffffffff); } else { flash_program_word((uint32_t) pinfailsptr, 0); } flash_lock(); storage_check_flash_errors(); } bool storage_increasePinFails(uint32_t *pinfailsptr) { uint32_t newctr = *pinfailsptr << 1; // counter already at maximum, we do not increase it any more // return success so that a good pin is accepted if (!newctr) return true; flash_clear_status_flags(); flash_unlock(); flash_program_word((uint32_t) pinfailsptr, newctr); flash_lock(); storage_check_flash_errors(); return *pinfailsptr == newctr; } uint32_t *storage_getPinFailsPtr(void) { uint32_t *pinfailsptr = (uint32_t *) FLASH_STORAGE_PINAREA; while (*pinfailsptr == 0) pinfailsptr++; return pinfailsptr; } bool storage_isInitialized(void) { return storage.has_node || storage.has_mnemonic; } uint32_t storage_getU2FCounter(void) { return storage.u2f_counter + storage_u2f_offset; } uint32_t storage_nextU2FCounter(void) { uint32_t *ptr = ((uint32_t *) FLASH_STORAGE_U2FAREA) + (storage_u2f_offset / 32); uint32_t newval = 0xfffffffe << (storage_u2f_offset & 31); flash_clear_status_flags(); flash_unlock(); flash_program_word((uint32_t) ptr, newval); storage_u2f_offset++; if (storage_u2f_offset >= 8 * FLASH_STORAGE_U2FAREA_LEN) { storage_area_recycle(*storage_getPinFailsPtr()); } flash_lock(); storage_check_flash_errors(); return storage.u2f_counter + storage_u2f_offset; }