mirror of
https://github.com/markqvist/OpenModem.git
synced 2024-12-25 23:49:27 -05:00
256 lines
5.8 KiB
C
256 lines
5.8 KiB
C
#include "Crypto.h"
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#include "util/Config.h"
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bool encryption_enabled = false;
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uint8_t active_key[CRYPTO_KEY_SIZE];
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uint8_t active_iv[CRYPTO_KEY_SIZE];
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aes_128_context_t context;
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uint8_t current_vector[CRYPTO_KEY_SIZE];
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uint32_t entropy;
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uint32_t entropy_index = 0;
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bool entropy_loaded = false;
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uint8_t ivs_generated = 0;
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FIL crypto_fp; // File buffer
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char crypto_fb[CRYPTO_KEY_SIZE]; // File read buffer
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FRESULT crypto_fr; // Result codes
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void crypto_init(void) {
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encryption_enabled = false;
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if (should_disable_enryption()) {
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if (config_crypto_lock) config_crypto_lock_disable();
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} else {
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if (load_key()) {
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if (load_entropy_index() && load_entropy()) {
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config_crypto_lock_enable();
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encryption_enabled = true;
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}
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}
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if (config_crypto_lock) {
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if (encryption_enabled) {
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LED_indicate_enabled_crypto();
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} else {
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LED_indicate_error_crypto();
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}
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}
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}
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}
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bool crypto_wait(void) {
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size_t wait_timer = 0;
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size_t interval_ms = 100;
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while (!crypto_enabled()) {
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delay_ms(100);
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wait_timer++;
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sd_jobs();
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if (wait_timer*interval_ms > CRYPTO_WAIT_TIMEOUT_MS) {
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return false;
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}
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}
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return true;
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}
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void crypto_generate_hmac(uint8_t *data, size_t length) {
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hmac_md5(crypto_work_block, active_key, CRYPTO_KEY_SIZE_BITS, data, length*8);
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}
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bool crypto_enabled(void) {
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return encryption_enabled;
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}
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void crypto_prepare(void) {
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// Initialise the context with the key
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aes_128_init(&context, active_key);
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// Copy the IV into the current vector array
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memcpy(current_vector, active_iv, CRYPTO_KEY_SIZE);
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}
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void crypto_encrypt_block(uint8_t block[CRYPTO_KEY_SIZE]) {
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int i;
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// XOR the current vector with the block before encrypting
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for (i = 0; i < CRYPTO_KEY_SIZE; i++) {
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block[i] ^= current_vector[i];
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}
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// Encrypt the block
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aes_128_encrypt(&context, block);
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// Copy the cipher output to the current vector
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memcpy(current_vector, block, CRYPTO_KEY_SIZE);
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}
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void crypto_decrypt_block(uint8_t block[CRYPTO_KEY_SIZE]) {
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uint8_t temp_vector[CRYPTO_KEY_SIZE];
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int i;
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// Copy the cipher output to the temporary vector
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memcpy(temp_vector, block, CRYPTO_KEY_SIZE);
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// Decrypt the block
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aes_128_decrypt(&context, block);
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// XOR the output with the current vector to fully decrypt
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for (i = 0; i < CRYPTO_KEY_SIZE; i++) {
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block[i] ^= current_vector[i];
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}
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// Copy the temporary vector to the current vector
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memcpy(current_vector, temp_vector, CRYPTO_KEY_SIZE);
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}
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bool load_entropy_index(void) {
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if (sd_mounted()) {
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crypto_fr = f_open(&crypto_fp, PATH_ENTROPY_INDEX, FA_READ);
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if (crypto_fr == FR_NO_FILE) {
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f_close(&crypto_fp);
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crypto_fr = f_open(&crypto_fp, PATH_ENTROPY_INDEX, FA_CREATE_NEW | FA_WRITE);
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if (crypto_fr == FR_OK) {
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entropy_index = 0x00000000;
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memcpy(crypto_fb, &entropy_index, sizeof(entropy_index));
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UINT written = 0;
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crypto_fr = f_write(&crypto_fp, crypto_fb, sizeof(entropy_index), &written);
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f_close(&crypto_fp);
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if (crypto_fr == FR_OK && written == sizeof(entropy_index)) {
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//printf("Wrote new index to index file\r\n");
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} else {
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//printf("Could not write index to index file\r\n");
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}
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}
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crypto_fr = f_open(&crypto_fp, PATH_ENTROPY_INDEX, FA_READ);
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}
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if (crypto_fr == FR_OK) {
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UINT read = 0;
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crypto_fr = f_read(&crypto_fp, crypto_fb, sizeof(entropy_index), &read);
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f_close(&crypto_fp);
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if (crypto_fr == FR_OK && read == sizeof(entropy_index)) {
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memcpy(&entropy_index, crypto_fb, sizeof(entropy_index));
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return true;
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}
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}
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}
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f_close(&crypto_fp);
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return false;
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}
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bool update_entropy_index(void) {
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crypto_fr = f_open(&crypto_fp, PATH_ENTROPY_INDEX, FA_WRITE);
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if (crypto_fr == FR_OK) {
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entropy_index += sizeof(entropy);
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memcpy(crypto_fb, &entropy_index, sizeof(entropy_index));
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UINT written = 0;
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crypto_fr = f_write(&crypto_fp, crypto_fb, sizeof(entropy_index), &written);
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f_close(&crypto_fp);
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if (crypto_fr == FR_OK && written == sizeof(entropy_index)) {
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return true;
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}
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}
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return false;
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}
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bool load_entropy(void) {
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if (sd_mounted()) {
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if (update_entropy_index()) {
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crypto_fr = f_open(&crypto_fp, PATH_ENTROPY_SOURCE, FA_READ);
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if (crypto_fr == FR_OK) {
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uint32_t fsize = f_size(&crypto_fp);
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crypto_fr = f_lseek(&crypto_fp, entropy_index);
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if (crypto_fr == FR_OK && crypto_fp.fptr < fsize-sizeof(entropy)) {
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UINT read = 0;
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crypto_fr = f_read(&crypto_fp, crypto_fb, sizeof(entropy), &read);
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f_close(&crypto_fp);
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if (crypto_fr == FR_OK) {
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memcpy(&entropy, crypto_fb, sizeof(entropy));
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srandom(entropy);
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entropy_loaded = true;
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ivs_generated = 0;
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return true;
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}
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} else {
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f_close(&crypto_fp);
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LED_indicate_error_crypto();
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}
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}
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}
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}
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f_close(&crypto_fp);
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return false;
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}
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bool should_disable_enryption(void) {
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if (sd_mounted()) {
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crypto_fr = f_open(&crypto_fp, PATH_CRYPTO_DISABLE, FA_READ);
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if (crypto_fr == FR_OK) {
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f_close(&crypto_fp);
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return true;
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}
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}
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return false;
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}
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bool load_key(void) {
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if (sd_mounted()) {
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crypto_fr = f_open(&crypto_fp, PATH_AES_128_KEY, FA_READ);
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if (crypto_fr == FR_OK) {
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UINT read = 0;
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crypto_fr = f_read(&crypto_fp, crypto_fb, CRYPTO_KEY_SIZE, &read);
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f_close(&crypto_fp);
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if (crypto_fr == FR_OK && read == CRYPTO_KEY_SIZE) {
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for (uint8_t i = 0; i < 16; i++) {
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active_key[i] = crypto_fb[i];
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}
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return true;
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}
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}
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}
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return false;
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}
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bool crypto_generate_iv(void) {
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if (entropy_loaded) {
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for (uint8_t i = 0; i < 16; i++) {
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active_iv[i] = (uint8_t)random();
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}
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ivs_generated++;
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if (ivs_generated >= MAX_IVS_PER_ENTROPY_BLOCK) {
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load_entropy();
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}
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return true;
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} else {
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return false;
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}
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}
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uint8_t *crypto_get_iv(void) {
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return active_iv;
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}
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void crypto_set_iv_from_workblock(void) {
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memcpy(active_iv, crypto_work_block, CRYPTO_KEY_SIZE);
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}
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// TODO: test entropy exhaustion
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