c964099c8c
* Fix U2F counter endianness * Increment U2F counter before using it * U2F: increment counter before use * U2F: don't increment on U2fCheckOnly Co-authored-by: Aleksandr Kutuzov <alleteam@gmail.com>
363 lines
10 KiB
C
363 lines
10 KiB
C
#include <furi.h>
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#include "u2f.h"
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#include "u2f_hid.h"
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#include "u2f_data.h"
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#include <furi_hal.h>
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#include <furi_hal_random.h>
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#include <littlefs/lfs_util.h> // for lfs_tobe32
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#include "toolbox/sha256.h"
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#include "toolbox/hmac_sha256.h"
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#include "micro-ecc/uECC.h"
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#define TAG "U2F"
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#define WORKER_TAG TAG "Worker"
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#define U2F_CMD_REGISTER 0x01
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#define U2F_CMD_AUTHENTICATE 0x02
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#define U2F_CMD_VERSION 0x03
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typedef enum {
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U2fCheckOnly = 0x07, // "check-only" - only check key handle, don't send auth response
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U2fEnforce =
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0x03, // "enforce-user-presence-and-sign" - send auth response only if user is present
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U2fDontEnforce =
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0x08, // "dont-enforce-user-presence-and-sign" - send auth response even if user is missing
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} U2fAuthMode;
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typedef struct {
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uint8_t format;
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uint8_t xy[64];
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} __attribute__((packed)) U2fPubKey;
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typedef struct {
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uint8_t len;
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uint8_t hash[32];
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uint8_t nonce[32];
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} __attribute__((packed)) U2fKeyHandle;
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typedef struct {
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uint8_t cla;
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uint8_t ins;
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uint8_t p1;
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uint8_t p2;
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uint8_t len[3];
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uint8_t challenge[32];
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uint8_t app_id[32];
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} __attribute__((packed)) U2fRegisterReq;
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typedef struct {
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uint8_t reserved;
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U2fPubKey pub_key;
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U2fKeyHandle key_handle;
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uint8_t cert[];
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} __attribute__((packed)) U2fRegisterResp;
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typedef struct {
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uint8_t cla;
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uint8_t ins;
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uint8_t p1;
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uint8_t p2;
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uint8_t len[3];
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uint8_t challenge[32];
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uint8_t app_id[32];
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U2fKeyHandle key_handle;
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} __attribute__((packed)) U2fAuthReq;
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typedef struct {
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uint8_t user_present;
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uint32_t counter;
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uint8_t signature[];
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} __attribute__((packed)) U2fAuthResp;
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static const uint8_t ver_str[] = {"U2F_V2"};
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static const uint8_t state_no_error[] = {0x90, 0x00};
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static const uint8_t state_not_supported[] = {0x6D, 0x00};
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static const uint8_t state_user_missing[] = {0x69, 0x85};
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static const uint8_t state_wrong_data[] = {0x6A, 0x80};
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struct U2fData {
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uint8_t device_key[32];
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uint8_t cert_key[32];
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uint32_t counter;
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const struct uECC_Curve_t* p_curve;
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bool ready;
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bool user_present;
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U2fEvtCallback callback;
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void* context;
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};
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static int u2f_uecc_random(uint8_t* dest, unsigned size) {
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furi_hal_random_fill_buf(dest, size);
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return 1;
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}
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U2fData* u2f_alloc() {
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return malloc(sizeof(U2fData));
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}
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void u2f_free(U2fData* U2F) {
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furi_assert(U2F);
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free(U2F);
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}
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bool u2f_init(U2fData* U2F) {
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furi_assert(U2F);
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if(u2f_data_cert_check() == false) {
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FURI_LOG_E(TAG, "Certificate load error");
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return false;
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}
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if(u2f_data_cert_key_load(U2F->cert_key) == false) {
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FURI_LOG_E(TAG, "Certificate key load error");
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return false;
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}
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if(u2f_data_key_load(U2F->device_key) == false) {
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FURI_LOG_W(TAG, "Key loading error, generating new");
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if(u2f_data_key_generate(U2F->device_key) == false) {
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FURI_LOG_E(TAG, "Key write failed");
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return false;
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}
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}
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if(u2f_data_cnt_read(&U2F->counter) == false) {
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FURI_LOG_W(TAG, "Counter loading error, resetting counter");
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U2F->counter = 0;
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if(u2f_data_cnt_write(0) == false) {
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FURI_LOG_E(TAG, "Counter write failed");
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return false;
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}
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}
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U2F->p_curve = uECC_secp256r1();
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uECC_set_rng(u2f_uecc_random);
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U2F->ready = true;
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return true;
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}
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void u2f_set_event_callback(U2fData* U2F, U2fEvtCallback callback, void* context) {
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furi_assert(U2F);
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furi_assert(callback);
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U2F->callback = callback;
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U2F->context = context;
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}
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void u2f_confirm_user_present(U2fData* U2F) {
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U2F->user_present = true;
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}
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static uint8_t u2f_der_encode_int(uint8_t* der, uint8_t* val, uint8_t val_len) {
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der[0] = 0x02; // Integer
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uint8_t len = 2;
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// Omit leading zeros
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while(val[0] == 0 && val_len > 0) {
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++val;
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--val_len;
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}
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// Check if integer is negative
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if(val[0] > 0x7f) der[len++] = 0;
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memcpy(der + len, val, val_len);
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len += val_len;
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der[1] = len - 2;
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return len;
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}
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static uint8_t u2f_der_encode_signature(uint8_t* der, uint8_t* sig) {
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der[0] = 0x30;
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uint8_t len = 2;
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len += u2f_der_encode_int(der + len, sig, 32);
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len += u2f_der_encode_int(der + len, sig + 32, 32);
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der[1] = len - 2;
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return len;
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}
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static uint16_t u2f_register(U2fData* U2F, uint8_t* buf) {
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U2fRegisterReq* req = (U2fRegisterReq*)buf;
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U2fRegisterResp* resp = (U2fRegisterResp*)buf;
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U2fKeyHandle handle;
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uint8_t private[32];
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U2fPubKey pub_key;
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uint8_t hash[32];
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uint8_t signature[64];
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if(u2f_data_check(false) == false) {
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U2F->ready = false;
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if(U2F->callback != NULL) U2F->callback(U2fNotifyError, U2F->context);
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memcpy(&buf[0], state_not_supported, 2);
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return 2;
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}
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if(U2F->callback != NULL) U2F->callback(U2fNotifyRegister, U2F->context);
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if(U2F->user_present == false) {
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memcpy(&buf[0], state_user_missing, 2);
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return 2;
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}
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U2F->user_present = false;
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hmac_sha256_context hmac_ctx;
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sha256_context sha_ctx;
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handle.len = 32 * 2;
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// Generate random nonce
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furi_hal_random_fill_buf(handle.nonce, 32);
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// Generate private key
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hmac_sha256_init(&hmac_ctx, U2F->device_key);
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hmac_sha256_update(&hmac_ctx, req->app_id, 32);
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hmac_sha256_update(&hmac_ctx, handle.nonce, 32);
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hmac_sha256_finish(&hmac_ctx, U2F->device_key, private);
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// Generate private key handle
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hmac_sha256_init(&hmac_ctx, U2F->device_key);
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hmac_sha256_update(&hmac_ctx, private, 32);
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hmac_sha256_update(&hmac_ctx, req->app_id, 32);
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hmac_sha256_finish(&hmac_ctx, U2F->device_key, handle.hash);
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// Generate public key
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pub_key.format = 0x04; // Uncompressed point
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uECC_compute_public_key(private, pub_key.xy, U2F->p_curve);
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// Generate signature
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uint8_t reserved_byte = 0;
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sha256_start(&sha_ctx);
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sha256_update(&sha_ctx, &reserved_byte, 1);
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sha256_update(&sha_ctx, req->app_id, 32);
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sha256_update(&sha_ctx, req->challenge, 32);
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sha256_update(&sha_ctx, handle.hash, handle.len);
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sha256_update(&sha_ctx, (uint8_t*)&pub_key, 65);
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sha256_finish(&sha_ctx, hash);
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uECC_sign(U2F->cert_key, hash, 32, signature, U2F->p_curve);
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// Encode response message
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resp->reserved = 0x05;
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memcpy(&(resp->pub_key), &pub_key, sizeof(U2fPubKey));
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memcpy(&(resp->key_handle), &handle, sizeof(U2fKeyHandle));
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uint32_t cert_len = u2f_data_cert_load(resp->cert);
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uint8_t signature_len = u2f_der_encode_signature(resp->cert + cert_len, signature);
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memcpy(resp->cert + cert_len + signature_len, state_no_error, 2);
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return (sizeof(U2fRegisterResp) + cert_len + signature_len + 2);
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}
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static uint16_t u2f_authenticate(U2fData* U2F, uint8_t* buf) {
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U2fAuthReq* req = (U2fAuthReq*)buf;
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U2fAuthResp* resp = (U2fAuthResp*)buf;
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uint8_t priv_key[32];
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uint8_t mac_control[32];
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hmac_sha256_context hmac_ctx;
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sha256_context sha_ctx;
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uint8_t flags = 0;
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uint8_t hash[32];
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uint8_t signature[64];
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uint32_t be_u2f_counter;
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if(u2f_data_check(false) == false) {
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U2F->ready = false;
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if(U2F->callback != NULL) U2F->callback(U2fNotifyError, U2F->context);
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memcpy(&buf[0], state_not_supported, 2);
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return 2;
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}
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if(U2F->callback != NULL) U2F->callback(U2fNotifyAuth, U2F->context);
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if(U2F->user_present == true) {
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flags |= 1;
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} else {
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if(req->p1 == U2fEnforce) {
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memcpy(&buf[0], state_user_missing, 2);
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return 2;
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}
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}
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U2F->user_present = false;
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// The 4 byte counter is represented in big endian. Increment it before use
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be_u2f_counter = lfs_tobe32(U2F->counter + 1);
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// Generate hash
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sha256_start(&sha_ctx);
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sha256_update(&sha_ctx, req->app_id, 32);
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sha256_update(&sha_ctx, &flags, 1);
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sha256_update(&sha_ctx, (uint8_t*)&(be_u2f_counter), 4);
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sha256_update(&sha_ctx, req->challenge, 32);
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sha256_finish(&sha_ctx, hash);
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// Recover private key
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hmac_sha256_init(&hmac_ctx, U2F->device_key);
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hmac_sha256_update(&hmac_ctx, req->app_id, 32);
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hmac_sha256_update(&hmac_ctx, req->key_handle.nonce, 32);
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hmac_sha256_finish(&hmac_ctx, U2F->device_key, priv_key);
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// Generate and verify private key handle
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hmac_sha256_init(&hmac_ctx, U2F->device_key);
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hmac_sha256_update(&hmac_ctx, priv_key, 32);
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hmac_sha256_update(&hmac_ctx, req->app_id, 32);
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hmac_sha256_finish(&hmac_ctx, U2F->device_key, mac_control);
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if(memcmp(req->key_handle.hash, mac_control, 32) != 0) {
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FURI_LOG_W(TAG, "Wrong handle!");
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memcpy(&buf[0], state_wrong_data, 2);
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return 2;
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}
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if(req->p1 == U2fCheckOnly) { // Check-only: don't need to send full response
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memcpy(&buf[0], state_user_missing, 2);
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return 2;
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}
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uECC_sign(priv_key, hash, 32, signature, U2F->p_curve);
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resp->user_present = flags;
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resp->counter = be_u2f_counter;
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uint8_t signature_len = u2f_der_encode_signature(resp->signature, signature);
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memcpy(resp->signature + signature_len, state_no_error, 2);
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U2F->counter++;
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FURI_LOG_D(TAG, "Counter: %lu", U2F->counter);
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u2f_data_cnt_write(U2F->counter);
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if(U2F->callback != NULL) U2F->callback(U2fNotifyAuthSuccess, U2F->context);
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return (sizeof(U2fAuthResp) + signature_len + 2);
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}
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uint16_t u2f_msg_parse(U2fData* U2F, uint8_t* buf, uint16_t len) {
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furi_assert(U2F);
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if(!U2F->ready) return 0;
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if((buf[0] != 0x00) && (len < 5)) return 0;
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if(buf[1] == U2F_CMD_REGISTER) { // Register request
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return u2f_register(U2F, buf);
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} else if(buf[1] == U2F_CMD_AUTHENTICATE) { // Authenticate request
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return u2f_authenticate(U2F, buf);
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} else if(buf[1] == U2F_CMD_VERSION) { // Get U2F version string
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memcpy(&buf[0], ver_str, 6);
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memcpy(&buf[6], state_no_error, 2);
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return 8;
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} else {
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memcpy(&buf[0], state_not_supported, 2);
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return 2;
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}
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return 0;
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}
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void u2f_wink(U2fData* U2F) {
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if(U2F->callback != NULL) U2F->callback(U2fNotifyWink, U2F->context);
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}
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void u2f_set_state(U2fData* U2F, uint8_t state) {
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if(state == 0) {
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if(U2F->callback != NULL) U2F->callback(U2fNotifyDisconnect, U2F->context);
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} else {
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if(U2F->callback != NULL) U2F->callback(U2fNotifyConnect, U2F->context);
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}
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U2F->user_present = false;
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}
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