xref: /btstack/src/ble/sm.c (revision 13aed524df3cb5e60819e0b8444a39eb20812f51)

/*
 * Copyright (C) 2014 BlueKitchen GmbH
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 * 3. Neither the name of the copyright holders nor the names of
 *    contributors may be used to endorse or promote products derived
 *    from this software without specific prior written permission.
 * 4. Any redistribution, use, or modification is done solely for
 *    personal benefit and not for any commercial purpose or for
 *    monetary gain.
 *
 * THIS SOFTWARE IS PROVIDED BY BLUEKITCHEN GMBH AND CONTRIBUTORS
 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL BLUEKITCHEN
 * GMBH OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF
 * THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 * SUCH DAMAGE.
 *
 * Please inquire about commercial licensing options at
 * [email protected]
 *
 */

#define BTSTACK_FILE__ "sm.c"

#include <string.h>
#include <inttypes.h>

#include "ble/le_device_db.h"
#include "ble/core.h"
#include "ble/sm.h"
#include "bluetooth_company_id.h"
#include "btstack_bool.h"
#include "btstack_crypto.h"
#include "btstack_debug.h"
#include "btstack_event.h"
#include "btstack_linked_list.h"
#include "btstack_memory.h"
#include "btstack_tlv.h"
#include "gap.h"
#include "hci.h"
#include "hci_dump.h"
#include "l2cap.h"

#if !defined(ENABLE_LE_PERIPHERAL) && !defined(ENABLE_LE_CENTRAL)
#error "LE Security Manager used, but neither ENABLE_LE_PERIPHERAL nor ENABLE_LE_CENTRAL defined. Please add at least one to btstack_config.h."
#endif

#if defined(ENABLE_CROSS_TRANSPORT_KEY_DERIVATION) && (!defined(ENABLE_CLASSIC) || !defined(ENABLE_LE_SECURE_CONNECTIONS))
#error "Cross Transport Key Derivation requires support for LE Secure Connections and BR/EDR (Classic)"
#endif

// assert SM Public Key can be sent/received
#ifdef ENABLE_LE_SECURE_CONNECTIONS
#if HCI_ACL_PAYLOAD_SIZE < 69
#error "HCI_ACL_PAYLOAD_SIZE must be at least 69 bytes when using LE Secure Conection. Please increase HCI_ACL_PAYLOAD_SIZE or disable ENABLE_LE_SECURE_CONNECTIONS"
#endif
#endif

#if defined(ENABLE_LE_PERIPHERAL) && defined(ENABLE_LE_CENTRAL)
#define IS_RESPONDER(role) (role)
#else
#ifdef ENABLE_LE_CENTRAL
// only central - never responder (avoid 'unused variable' warnings)
#define IS_RESPONDER(role) (0 && role)
#else
// only peripheral - always responder (avoid 'unused variable' warnings)
#define IS_RESPONDER(role) (1 || role)
#endif
#endif

#if defined(ENABLE_LE_SIGNED_WRITE) || defined(ENABLE_LE_SECURE_CONNECTIONS)
#define USE_CMAC_ENGINE
#endif


#define BTSTACK_TAG32(A,B,C,D) (((A) << 24) | ((B) << 16) | ((C) << 8) | (D))

//
// SM internal types and globals
//

typedef enum {
    DKG_W4_WORKING,
    DKG_CALC_IRK,
    DKG_CALC_DHK,
    DKG_READY
} derived_key_generation_t;

typedef enum {
    RAU_IDLE,
    RAU_GET_RANDOM,
    RAU_W4_RANDOM,
    RAU_GET_ENC,
    RAU_W4_ENC,
} random_address_update_t;

typedef enum {
    CMAC_IDLE,
    CMAC_CALC_SUBKEYS,
    CMAC_W4_SUBKEYS,
    CMAC_CALC_MI,
    CMAC_W4_MI,
    CMAC_CALC_MLAST,
    CMAC_W4_MLAST
} cmac_state_t;

typedef enum {
    JUST_WORKS,
    PK_RESP_INPUT,       // Initiator displays PK, responder inputs PK
    PK_INIT_INPUT,       // Responder displays PK, initiator inputs PK
    PK_BOTH_INPUT,       // Only input on both, both input PK
    NUMERIC_COMPARISON,  // Only numerical compparison (yes/no) on on both sides
    OOB                  // OOB available on one (SC) or both sides (legacy)
} stk_generation_method_t;

typedef enum {
    SM_USER_RESPONSE_IDLE,
    SM_USER_RESPONSE_PENDING,
    SM_USER_RESPONSE_CONFIRM,
    SM_USER_RESPONSE_PASSKEY,
    SM_USER_RESPONSE_DECLINE
} sm_user_response_t;

typedef enum {
    SM_AES128_IDLE,
    SM_AES128_ACTIVE
} sm_aes128_state_t;

typedef enum {
    ADDRESS_RESOLUTION_IDLE,
    ADDRESS_RESOLUTION_GENERAL,
    ADDRESS_RESOLUTION_FOR_CONNECTION,
} address_resolution_mode_t;

typedef enum {
    ADDRESS_RESOLUTION_SUCCEEDED,
    ADDRESS_RESOLUTION_FAILED,
} address_resolution_event_t;

typedef enum {
    EC_KEY_GENERATION_IDLE,
    EC_KEY_GENERATION_ACTIVE,
    EC_KEY_GENERATION_DONE,
} ec_key_generation_state_t;

typedef enum {
    SM_STATE_VAR_DHKEY_NEEDED = 1 << 0,
    SM_STATE_VAR_DHKEY_CALCULATED = 1 << 1,
    SM_STATE_VAR_DHKEY_COMMAND_RECEIVED = 1 << 2,
} sm_state_var_t;

typedef enum {
    SM_SC_OOB_IDLE,
    SM_SC_OOB_W4_RANDOM,
    SM_SC_OOB_W2_CALC_CONFIRM,
    SM_SC_OOB_W4_CONFIRM,
} sm_sc_oob_state_t;

typedef uint8_t sm_key24_t[3];
typedef uint8_t sm_key56_t[7];
typedef uint8_t sm_key256_t[32];

//
// GLOBAL DATA
//

static bool sm_initialized;

static bool test_use_fixed_local_csrk;
static bool test_use_fixed_local_irk;

#ifdef ENABLE_TESTING_SUPPORT
static uint8_t test_pairing_failure;
#endif

// configuration
static uint8_t sm_accepted_stk_generation_methods;
static uint8_t sm_max_encryption_key_size;
static uint8_t sm_min_encryption_key_size;
static uint8_t sm_auth_req = 0;
static uint8_t sm_io_capabilities = IO_CAPABILITY_NO_INPUT_NO_OUTPUT;
static uint32_t sm_fixed_passkey_in_display_role;
static bool sm_reconstruct_ltk_without_le_device_db_entry;

#ifdef ENABLE_LE_PERIPHERAL
static uint8_t sm_slave_request_security;
#endif

#ifdef ENABLE_LE_SECURE_CONNECTIONS
static bool sm_sc_only_mode;
static uint8_t sm_sc_oob_random[16];
static void (*sm_sc_oob_callback)(const uint8_t * confirm_value, const uint8_t * random_value);
static sm_sc_oob_state_t sm_sc_oob_state;
#endif


static bool                  sm_persistent_keys_random_active;
static const btstack_tlv_t * sm_tlv_impl;
static void *                sm_tlv_context;

// Security Manager Master Keys, please use sm_set_er(er) and sm_set_ir(ir) with your own 128 bit random values
static sm_key_t sm_persistent_er;
static sm_key_t sm_persistent_ir;

// derived from sm_persistent_ir
static sm_key_t sm_persistent_dhk;
static sm_key_t sm_persistent_irk;
static derived_key_generation_t dkg_state;

// derived from sm_persistent_er
// ..

// random address update
static random_address_update_t rau_state;
static bd_addr_t sm_random_address;

#ifdef USE_CMAC_ENGINE
// CMAC Calculation: General
static btstack_crypto_aes128_cmac_t sm_cmac_request;
static void (*sm_cmac_done_callback)(uint8_t hash[8]);
static uint8_t sm_cmac_active;
static uint8_t sm_cmac_hash[16];
#endif

// CMAC for ATT Signed Writes
#ifdef ENABLE_LE_SIGNED_WRITE
static uint16_t        sm_cmac_signed_write_message_len;
static uint8_t         sm_cmac_signed_write_header[3];
static const uint8_t * sm_cmac_signed_write_message;
static uint8_t         sm_cmac_signed_write_sign_counter[4];
#endif

// CMAC for Secure Connection functions
#ifdef ENABLE_LE_SECURE_CONNECTIONS
static sm_connection_t * sm_cmac_connection;
static uint8_t           sm_cmac_sc_buffer[80];
#endif

// resolvable private address lookup / CSRK calculation
static int       sm_address_resolution_test;
static uint8_t   sm_address_resolution_addr_type;
static bd_addr_t sm_address_resolution_address;
static void *    sm_address_resolution_context;
static address_resolution_mode_t sm_address_resolution_mode;
static btstack_linked_list_t sm_address_resolution_general_queue;

// aes128 crypto engine.
static sm_aes128_state_t  sm_aes128_state;

// crypto
static btstack_crypto_random_t   sm_crypto_random_request;
static btstack_crypto_aes128_t   sm_crypto_aes128_request;
#ifdef ENABLE_LE_SECURE_CONNECTIONS
static btstack_crypto_ecc_p256_t sm_crypto_ecc_p256_request;
#endif

// temp storage for random data
static uint8_t sm_random_data[8];
static uint8_t sm_aes128_key[16];
static uint8_t sm_aes128_plaintext[16];
static uint8_t sm_aes128_ciphertext[16];

// to receive events
static btstack_packet_callback_registration_t hci_event_callback_registration;
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
static btstack_packet_callback_registration_t l2cap_event_callback_registration;
#endif

/* to dispatch sm event */
static btstack_linked_list_t sm_event_handlers;

/* to schedule calls to sm_run */
static btstack_timer_source_t sm_run_timer;

// LE Secure Connections
#ifdef ENABLE_LE_SECURE_CONNECTIONS
static ec_key_generation_state_t ec_key_generation_state;
static uint8_t ec_q[64];
#endif

//
// Volume 3, Part H, Chapter 24
// "Security shall be initiated by the Security Manager in the device in the master role.
// The device in the slave role shall be the responding device."
// -> master := initiator, slave := responder
//

// data needed for security setup
typedef struct sm_setup_context {

    btstack_timer_source_t sm_timeout;

    // user response, (Phase 1 and/or 2)
    uint8_t   sm_user_response;
    uint8_t   sm_keypress_notification; // bitmap: passkey started, digit entered, digit erased, passkey cleared, passkey complete, 3 bit count

    // defines which keys will be send after connection is encrypted - calculated during Phase 1, used Phase 3
    uint8_t   sm_key_distribution_send_set;
    uint8_t   sm_key_distribution_sent_set;
    uint8_t   sm_key_distribution_expected_set;
    uint8_t   sm_key_distribution_received_set;

    // Phase 2 (Pairing over SMP)
    stk_generation_method_t sm_stk_generation_method;
    sm_key_t  sm_tk;
    uint8_t   sm_have_oob_data;
    uint8_t   sm_use_secure_connections;

    sm_key_t  sm_c1_t3_value;   // c1 calculation
    sm_pairing_packet_t sm_m_preq; // pairing request - needed only for c1
    sm_pairing_packet_t sm_s_pres; // pairing response - needed only for c1
    sm_key_t  sm_local_random;
    sm_key_t  sm_local_confirm;
    sm_key_t  sm_peer_random;
    sm_key_t  sm_peer_confirm;
    uint8_t   sm_m_addr_type;   // address and type can be removed
    uint8_t   sm_s_addr_type;   //  ''
    bd_addr_t sm_m_address;     //  ''
    bd_addr_t sm_s_address;     //  ''
    sm_key_t  sm_ltk;

    uint8_t   sm_state_vars;
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    uint8_t   sm_peer_q[64];    // also stores random for EC key generation during init
    sm_key_t  sm_peer_nonce;    // might be combined with sm_peer_random
    sm_key_t  sm_local_nonce;   // might be combined with sm_local_random
    uint8_t   sm_dhkey[32];
    sm_key_t  sm_peer_dhkey_check;
    sm_key_t  sm_local_dhkey_check;
    sm_key_t  sm_ra;
    sm_key_t  sm_rb;
    sm_key_t  sm_t;             // used for f5 and h6
    sm_key_t  sm_mackey;
    uint8_t   sm_passkey_bit;   // also stores number of generated random bytes for EC key generation
#endif

    // Phase 3

    // key distribution, we generate
    uint16_t  sm_local_y;
    uint16_t  sm_local_div;
    uint16_t  sm_local_ediv;
    uint8_t   sm_local_rand[8];
    sm_key_t  sm_local_ltk;
    sm_key_t  sm_local_csrk;
    sm_key_t  sm_local_irk;
    // sm_local_address/addr_type not needed

    // key distribution, received from peer
    uint16_t  sm_peer_y;
    uint16_t  sm_peer_div;
    uint16_t  sm_peer_ediv;
    uint8_t   sm_peer_rand[8];
    sm_key_t  sm_peer_ltk;
    sm_key_t  sm_peer_irk;
    sm_key_t  sm_peer_csrk;
    uint8_t   sm_peer_addr_type;
    bd_addr_t sm_peer_address;
#ifdef ENABLE_LE_SIGNED_WRITE
    int       sm_le_device_index;
#endif
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
    link_key_t sm_link_key;
    link_key_type_t sm_link_key_type;
#endif
} sm_setup_context_t;

//
static sm_setup_context_t the_setup;
static sm_setup_context_t * setup = &the_setup;

// active connection - the one for which the_setup is used for
static uint16_t sm_active_connection_handle = HCI_CON_HANDLE_INVALID;

// @return 1 if oob data is available
// stores oob data in provided 16 byte buffer if not null
static int (*sm_get_oob_data)(uint8_t addres_type, bd_addr_t addr, uint8_t * oob_data) = NULL;
static int (*sm_get_sc_oob_data)(uint8_t addres_type, bd_addr_t addr, uint8_t * oob_sc_peer_confirm, uint8_t * oob_sc_peer_random);
static bool (*sm_get_ltk_callback)(hci_con_handle_t con_handle, uint8_t addres_type, bd_addr_t addr, uint8_t * ltk);

static void sm_run(void);
static void sm_state_reset(void);
static void sm_done_for_handle(hci_con_handle_t con_handle);
static sm_connection_t * sm_get_connection_for_handle(hci_con_handle_t con_handle);
static void sm_cache_ltk(sm_connection_t * connection, const sm_key_t ltk);
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
static sm_connection_t * sm_get_connection_for_bd_addr_and_type(bd_addr_t address, bd_addr_type_t addr_type);
#endif
static inline int sm_calc_actual_encryption_key_size(int other);
static int sm_validate_stk_generation_method(void);
static void sm_handle_encryption_result_address_resolution(void *arg);
static void sm_handle_encryption_result_dkg_dhk(void *arg);
static void sm_handle_encryption_result_dkg_irk(void *arg);
static void sm_handle_encryption_result_enc_a(void *arg);
static void sm_handle_encryption_result_enc_b(void *arg);
static void sm_handle_encryption_result_enc_c(void *arg);
static void sm_handle_encryption_result_enc_csrk(void *arg);
static void sm_handle_encryption_result_enc_d(void * arg);
static void sm_handle_encryption_result_enc_ph3_ltk(void *arg);
static void sm_handle_encryption_result_enc_ph3_y(void *arg);
#ifdef ENABLE_LE_PERIPHERAL
static void sm_handle_encryption_result_enc_ph4_ltk(void *arg);
static void sm_handle_encryption_result_enc_ph4_y(void *arg);
#endif
static void sm_handle_encryption_result_enc_stk(void *arg);
static void sm_handle_encryption_result_rau(void *arg);
static void sm_handle_random_result_ph2_tk(void * arg);
static void sm_handle_random_result_rau(void * arg);
#ifdef ENABLE_LE_SECURE_CONNECTIONS
static void sm_cmac_message_start(const sm_key_t key, uint16_t message_len, const uint8_t * message, void (*done_callback)(uint8_t * hash));
static void sm_ec_generate_new_key(void);
static void sm_handle_random_result_sc_next_w2_cmac_for_confirmation(void * arg);
static void sm_handle_random_result_sc_next_send_pairing_random(void * arg);
static int sm_passkey_entry(stk_generation_method_t method);
#endif
static void sm_pairing_complete(sm_connection_t * sm_conn, uint8_t status, uint8_t reason);

static void log_info_hex16(const char * name, uint16_t value){
    log_info("%-6s 0x%04x", name, value);
}

// static inline uint8_t sm_pairing_packet_get_code(sm_pairing_packet_t packet){
//     return packet[0];
// }
static inline uint8_t sm_pairing_packet_get_io_capability(sm_pairing_packet_t packet){
    return packet[1];
}
static inline uint8_t sm_pairing_packet_get_oob_data_flag(sm_pairing_packet_t packet){
    return packet[2];
}
static inline uint8_t sm_pairing_packet_get_auth_req(sm_pairing_packet_t packet){
    return packet[3];
}
static inline uint8_t sm_pairing_packet_get_max_encryption_key_size(sm_pairing_packet_t packet){
    return packet[4];
}
static inline uint8_t sm_pairing_packet_get_initiator_key_distribution(sm_pairing_packet_t packet){
    return packet[5];
}
static inline uint8_t sm_pairing_packet_get_responder_key_distribution(sm_pairing_packet_t packet){
    return packet[6];
}

static inline void sm_pairing_packet_set_code(sm_pairing_packet_t packet, uint8_t code){
    packet[0] = code;
}
static inline void sm_pairing_packet_set_io_capability(sm_pairing_packet_t packet, uint8_t io_capability){
    packet[1] = io_capability;
}
static inline void sm_pairing_packet_set_oob_data_flag(sm_pairing_packet_t packet, uint8_t oob_data_flag){
    packet[2] = oob_data_flag;
}
static inline void sm_pairing_packet_set_auth_req(sm_pairing_packet_t packet, uint8_t auth_req){
    packet[3] = auth_req;
}
static inline void sm_pairing_packet_set_max_encryption_key_size(sm_pairing_packet_t packet, uint8_t max_encryption_key_size){
    packet[4] = max_encryption_key_size;
}
static inline void sm_pairing_packet_set_initiator_key_distribution(sm_pairing_packet_t packet, uint8_t initiator_key_distribution){
    packet[5] = initiator_key_distribution;
}
static inline void sm_pairing_packet_set_responder_key_distribution(sm_pairing_packet_t packet, uint8_t responder_key_distribution){
    packet[6] = responder_key_distribution;
}

static bool sm_is_null_random(uint8_t random[8]){
    return btstack_is_null(random, 8);
}

static bool sm_is_null_key(uint8_t * key){
    return btstack_is_null(key, 16);
}

// sm_trigger_run allows to schedule callback from main run loop // reduces stack depth
static void sm_run_timer_handler(btstack_timer_source_t * ts){
	UNUSED(ts);
	sm_run();
}
static void sm_trigger_run(void){
    if (!sm_initialized) return;
	(void)btstack_run_loop_remove_timer(&sm_run_timer);
	btstack_run_loop_set_timer(&sm_run_timer, 0);
	btstack_run_loop_add_timer(&sm_run_timer);
}

// Key utils
static void sm_reset_tk(void){
    int i;
    for (i=0;i<16;i++){
        setup->sm_tk[i] = 0;
    }
}

// "For example, if a 128-bit encryption key is 0x123456789ABCDEF0123456789ABCDEF0
// and it is reduced to 7 octets (56 bits), then the resulting key is 0x0000000000000000003456789ABCDEF0.""
static void sm_truncate_key(sm_key_t key, int max_encryption_size){
    int i;
    for (i = max_encryption_size ; i < 16 ; i++){
        key[15-i] = 0;
    }
}

// ER / IR checks
static void sm_er_ir_set_default(void){
    int i;
    for (i=0;i<16;i++){
        sm_persistent_er[i] = 0x30 + i;
        sm_persistent_ir[i] = 0x90 + i;
    }
}

static int sm_er_is_default(void){
    int i;
    for (i=0;i<16;i++){
        if (sm_persistent_er[i] != (0x30+i)) return 0;
    }
    return 1;
}

static int sm_ir_is_default(void){
    int i;
    for (i=0;i<16;i++){
        if (sm_persistent_ir[i] != (0x90+i)) return 0;
    }
    return 1;
}

static void sm_dispatch_event(uint8_t packet_type, uint16_t channel, uint8_t * packet, uint16_t size){
    UNUSED(channel);

    // log event
    hci_dump_packet(packet_type, 1, packet, size);
    // dispatch to all event handlers
    btstack_linked_list_iterator_t it;
    btstack_linked_list_iterator_init(&it, &sm_event_handlers);
    while (btstack_linked_list_iterator_has_next(&it)){
        btstack_packet_callback_registration_t * entry = (btstack_packet_callback_registration_t*) btstack_linked_list_iterator_next(&it);
        entry->callback(packet_type, 0, packet, size);
    }
}

static void sm_setup_event_base(uint8_t * event, int event_size, uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address){
    event[0] = type;
    event[1] = event_size - 2;
    little_endian_store_16(event, 2, con_handle);
    event[4] = addr_type;
    reverse_bd_addr(address, &event[5]);
}

static void sm_notify_client_base(uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address){
    uint8_t event[11];
    sm_setup_event_base(event, sizeof(event), type, con_handle, addr_type, address);
    sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event));
}

static void sm_notify_client_index(uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address, uint16_t index){
    // fetch addr and addr type from db, only called for valid entries
    bd_addr_t identity_address;
    int identity_address_type;
    le_device_db_info(index, &identity_address_type, identity_address, NULL);

    uint8_t event[20];
    sm_setup_event_base(event, sizeof(event), type, con_handle, addr_type, address);
    event[11] = identity_address_type;
    reverse_bd_addr(identity_address, &event[12]);
    little_endian_store_16(event, 18, index);
    sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event));
}

static void sm_notify_client_status(uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address, uint8_t status){
    uint8_t event[12];
    sm_setup_event_base(event, sizeof(event), type, con_handle, addr_type, address);
    event[11] = status;
    sm_dispatch_event(HCI_EVENT_PACKET, 0, (uint8_t*) &event, sizeof(event));
}


static void sm_reencryption_started(sm_connection_t * sm_conn){

    if (sm_conn->sm_reencryption_active) return;

    sm_conn->sm_reencryption_active = true;

    int       identity_addr_type;
    bd_addr_t identity_addr;
    if (sm_conn->sm_le_db_index >= 0){
        // fetch addr and addr type from db, only called for valid entries
        le_device_db_info(sm_conn->sm_le_db_index, &identity_addr_type, identity_addr, NULL);
    } else {
        // for legacy pairing with LTK re-construction, use current peer addr
        identity_addr_type = sm_conn->sm_peer_addr_type;
        // cppcheck-suppress uninitvar ; identity_addr is reported as uninitialized although it's the destination of the memcpy
        memcpy(identity_addr, sm_conn->sm_peer_address, 6);
    }

    sm_notify_client_base(SM_EVENT_REENCRYPTION_STARTED, sm_conn->sm_handle, identity_addr_type, identity_addr);
}

static void sm_reencryption_complete(sm_connection_t * sm_conn, uint8_t status){

    if (!sm_conn->sm_reencryption_active) return;

    sm_conn->sm_reencryption_active = false;

    int       identity_addr_type;
    bd_addr_t identity_addr;
    if (sm_conn->sm_le_db_index >= 0){
        // fetch addr and addr type from db, only called for valid entries
        le_device_db_info(sm_conn->sm_le_db_index, &identity_addr_type, identity_addr, NULL);
    } else {
        // for legacy pairing with LTK re-construction, use current peer addr
        identity_addr_type = sm_conn->sm_peer_addr_type;
        // cppcheck-suppress uninitvar ; identity_addr is reported as uninitialized although it's the destination of the memcpy
        memcpy(identity_addr, sm_conn->sm_peer_address, 6);
    }

    sm_notify_client_status(SM_EVENT_REENCRYPTION_COMPLETE, sm_conn->sm_handle, identity_addr_type, identity_addr, status);
}

static void sm_pairing_started(sm_connection_t * sm_conn){

    if (sm_conn->sm_pairing_active) return;

    sm_conn->sm_pairing_active = true;

    uint8_t event[11];
    sm_setup_event_base(event, sizeof(event), SM_EVENT_PAIRING_STARTED, sm_conn->sm_handle, setup->sm_peer_addr_type, setup->sm_peer_address);
    sm_dispatch_event(HCI_EVENT_PACKET, 0, (uint8_t*) &event, sizeof(event));
}

static void sm_pairing_complete(sm_connection_t * sm_conn, uint8_t status, uint8_t reason){

    if (!sm_conn->sm_pairing_active) return;

    sm_conn->sm_pairing_active = false;

    uint8_t event[13];
    sm_setup_event_base(event, sizeof(event), SM_EVENT_PAIRING_COMPLETE, sm_conn->sm_handle, setup->sm_peer_addr_type, setup->sm_peer_address);
    event[11] = status;
    event[12] = reason;
    sm_dispatch_event(HCI_EVENT_PACKET, 0, (uint8_t*) &event, sizeof(event));
}

// SMP Timeout implementation

// Upon transmission of the Pairing Request command or reception of the Pairing Request command,
// the Security Manager Timer shall be reset and started.
//
// The Security Manager Timer shall be reset when an L2CAP SMP command is queued for transmission.
//
// If the Security Manager Timer reaches 30 seconds, the procedure shall be considered to have failed,
// and the local higher layer shall be notified. No further SMP commands shall be sent over the L2CAP
// Security Manager Channel. A new SM procedure shall only be performed when a new physical link has been
// established.

static void sm_timeout_handler(btstack_timer_source_t * timer){
    log_info("SM timeout");
    sm_connection_t * sm_conn = (sm_connection_t*) btstack_run_loop_get_timer_context(timer);
    sm_conn->sm_engine_state = SM_GENERAL_TIMEOUT;
    sm_reencryption_complete(sm_conn, ERROR_CODE_CONNECTION_TIMEOUT);
    sm_pairing_complete(sm_conn, ERROR_CODE_CONNECTION_TIMEOUT, 0);
    sm_done_for_handle(sm_conn->sm_handle);

    // trigger handling of next ready connection
    sm_run();
}
static void sm_timeout_start(sm_connection_t * sm_conn){
    btstack_run_loop_remove_timer(&setup->sm_timeout);
    btstack_run_loop_set_timer_context(&setup->sm_timeout, sm_conn);
    btstack_run_loop_set_timer_handler(&setup->sm_timeout, sm_timeout_handler);
    btstack_run_loop_set_timer(&setup->sm_timeout, 30000); // 30 seconds sm timeout
    btstack_run_loop_add_timer(&setup->sm_timeout);
}
static void sm_timeout_stop(void){
    btstack_run_loop_remove_timer(&setup->sm_timeout);
}
static void sm_timeout_reset(sm_connection_t * sm_conn){
    sm_timeout_stop();
    sm_timeout_start(sm_conn);
}

// end of sm timeout

// GAP Random Address updates
static gap_random_address_type_t gap_random_adress_type;
static btstack_timer_source_t gap_random_address_update_timer;
static uint32_t gap_random_adress_update_period;

static void gap_random_address_trigger(void){
    log_info("gap_random_address_trigger, state %u", rau_state);
    if (rau_state != RAU_IDLE) return;
    rau_state = RAU_GET_RANDOM;
    sm_trigger_run();
}

static void gap_random_address_update_handler(btstack_timer_source_t * timer){
    UNUSED(timer);

    log_info("GAP Random Address Update due");
    btstack_run_loop_set_timer(&gap_random_address_update_timer, gap_random_adress_update_period);
    btstack_run_loop_add_timer(&gap_random_address_update_timer);
    gap_random_address_trigger();
}

static void gap_random_address_update_start(void){
    btstack_run_loop_set_timer_handler(&gap_random_address_update_timer, gap_random_address_update_handler);
    btstack_run_loop_set_timer(&gap_random_address_update_timer, gap_random_adress_update_period);
    btstack_run_loop_add_timer(&gap_random_address_update_timer);
}

static void gap_random_address_update_stop(void){
    btstack_run_loop_remove_timer(&gap_random_address_update_timer);
}

// ah(k,r) helper
// r = padding || r
// r - 24 bit value
static void sm_ah_r_prime(uint8_t r[3], uint8_t * r_prime){
    // r'= padding || r
    memset(r_prime, 0, 16);
    (void)memcpy(&r_prime[13], r, 3);
}

// d1 helper
// d' = padding || r || d
// d,r - 16 bit values
static void sm_d1_d_prime(uint16_t d, uint16_t r, uint8_t * d1_prime){
    // d'= padding || r || d
    memset(d1_prime, 0, 16);
    big_endian_store_16(d1_prime, 12, r);
    big_endian_store_16(d1_prime, 14, d);
}

// calculate arguments for first AES128 operation in C1 function
static void sm_c1_t1(sm_key_t r, uint8_t preq[7], uint8_t pres[7], uint8_t iat, uint8_t rat, uint8_t * t1){

    // p1 = pres || preq || rat’ || iat’
    // "The octet of iat’ becomes the least significant octet of p1 and the most signifi-
    // cant octet of pres becomes the most significant octet of p1.
    // For example, if the 8-bit iat’ is 0x01, the 8-bit rat’ is 0x00, the 56-bit preq
    // is 0x07071000000101 and the 56 bit pres is 0x05000800000302 then
    // p1 is 0x05000800000302070710000001010001."

    sm_key_t p1;
    reverse_56(pres, &p1[0]);
    reverse_56(preq, &p1[7]);
    p1[14] = rat;
    p1[15] = iat;
    log_info_key("p1", p1);
    log_info_key("r", r);

    // t1 = r xor p1
    int i;
    for (i=0;i<16;i++){
        t1[i] = r[i] ^ p1[i];
    }
    log_info_key("t1", t1);
}

// calculate arguments for second AES128 operation in C1 function
static void sm_c1_t3(sm_key_t t2, bd_addr_t ia, bd_addr_t ra, uint8_t * t3){
     // p2 = padding || ia || ra
    // "The least significant octet of ra becomes the least significant octet of p2 and
    // the most significant octet of padding becomes the most significant octet of p2.
    // For example, if 48-bit ia is 0xA1A2A3A4A5A6 and the 48-bit ra is
    // 0xB1B2B3B4B5B6 then p2 is 0x00000000A1A2A3A4A5A6B1B2B3B4B5B6.

    sm_key_t p2;
    // cppcheck-suppress uninitvar ; p2 is reported as uninitialized
    memset(p2, 0, 16);
    (void)memcpy(&p2[4], ia, 6);
    (void)memcpy(&p2[10], ra, 6);
    log_info_key("p2", p2);

    // c1 = e(k, t2_xor_p2)
    int i;
    for (i=0;i<16;i++){
        t3[i] = t2[i] ^ p2[i];
    }
    log_info_key("t3", t3);
}

static void sm_s1_r_prime(sm_key_t r1, sm_key_t r2, uint8_t * r_prime){
    log_info_key("r1", r1);
    log_info_key("r2", r2);
    (void)memcpy(&r_prime[8], &r2[8], 8);
    (void)memcpy(&r_prime[0], &r1[8], 8);
}


// decide on stk generation based on
// - pairing request
// - io capabilities
// - OOB data availability
static void sm_setup_tk(void){

    // horizontal: initiator capabilities
    // vertial:    responder capabilities
    static const stk_generation_method_t stk_generation_method [5] [5] = {
            { JUST_WORKS,      JUST_WORKS,       PK_INIT_INPUT,   JUST_WORKS,    PK_INIT_INPUT },
            { JUST_WORKS,      JUST_WORKS,       PK_INIT_INPUT,   JUST_WORKS,    PK_INIT_INPUT },
            { PK_RESP_INPUT,   PK_RESP_INPUT,    PK_BOTH_INPUT,   JUST_WORKS,    PK_RESP_INPUT },
            { JUST_WORKS,      JUST_WORKS,       JUST_WORKS,      JUST_WORKS,    JUST_WORKS    },
            { PK_RESP_INPUT,   PK_RESP_INPUT,    PK_INIT_INPUT,   JUST_WORKS,    PK_RESP_INPUT },
    };

    // uses numeric comparison if one side has DisplayYesNo and KeyboardDisplay combinations
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    static const stk_generation_method_t stk_generation_method_with_secure_connection[5][5] = {
            { JUST_WORKS,      JUST_WORKS,         PK_INIT_INPUT,   JUST_WORKS,    PK_INIT_INPUT      },
            { JUST_WORKS,      NUMERIC_COMPARISON, PK_INIT_INPUT,   JUST_WORKS,    NUMERIC_COMPARISON },
            { PK_RESP_INPUT,   PK_RESP_INPUT,      PK_BOTH_INPUT,   JUST_WORKS,    PK_RESP_INPUT      },
            { JUST_WORKS,      JUST_WORKS,         JUST_WORKS,      JUST_WORKS,    JUST_WORKS         },
            { PK_RESP_INPUT,   NUMERIC_COMPARISON, PK_INIT_INPUT,   JUST_WORKS,    NUMERIC_COMPARISON },
    };
#endif

    // default: just works
    setup->sm_stk_generation_method = JUST_WORKS;

#ifdef ENABLE_LE_SECURE_CONNECTIONS
    setup->sm_use_secure_connections = ( sm_pairing_packet_get_auth_req(setup->sm_m_preq)
                                       & sm_pairing_packet_get_auth_req(setup->sm_s_pres)
                                       & SM_AUTHREQ_SECURE_CONNECTION ) != 0u;
#else
    setup->sm_use_secure_connections = 0;
#endif
    log_info("Secure pairing: %u", setup->sm_use_secure_connections);


    // decide if OOB will be used based on SC vs. Legacy and oob flags
    bool use_oob;
    if (setup->sm_use_secure_connections){
        // In LE Secure Connections pairing, the out of band method is used if at least
        // one device has the peer device's out of band authentication data available.
        use_oob = (sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq) | sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres)) != 0;
    } else {
        // In LE legacy pairing, the out of band method is used if both the devices have
        // the other device's out of band authentication data available.
        use_oob = (sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq) & sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres)) != 0;
    }
    if (use_oob){
        log_info("SM: have OOB data");
        log_info_key("OOB", setup->sm_tk);
        setup->sm_stk_generation_method = OOB;
        return;
    }

    // If both devices have not set the MITM option in the Authentication Requirements
    // Flags, then the IO capabilities shall be ignored and the Just Works association
    // model shall be used.
    if (((sm_pairing_packet_get_auth_req(setup->sm_m_preq) & SM_AUTHREQ_MITM_PROTECTION) == 0u)
        &&  ((sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_MITM_PROTECTION) == 0u)){
        log_info("SM: MITM not required by both -> JUST WORKS");
        return;
    }

    // Reset TK as it has been setup in sm_init_setup
    sm_reset_tk();

    // Also use just works if unknown io capabilites
    if ((sm_pairing_packet_get_io_capability(setup->sm_m_preq) > IO_CAPABILITY_KEYBOARD_DISPLAY) || (sm_pairing_packet_get_io_capability(setup->sm_s_pres) > IO_CAPABILITY_KEYBOARD_DISPLAY)){
        return;
    }

    // Otherwise the IO capabilities of the devices shall be used to determine the
    // pairing method as defined in Table 2.4.
    // see http://stackoverflow.com/a/1052837/393697 for how to specify pointer to 2-dimensional array
    const stk_generation_method_t (*generation_method)[5] = stk_generation_method;

#ifdef ENABLE_LE_SECURE_CONNECTIONS
    // table not define by default
    if (setup->sm_use_secure_connections){
        generation_method = stk_generation_method_with_secure_connection;
    }
#endif
    setup->sm_stk_generation_method = generation_method[sm_pairing_packet_get_io_capability(setup->sm_s_pres)][sm_pairing_packet_get_io_capability(setup->sm_m_preq)];

    log_info("sm_setup_tk: master io cap: %u, slave io cap: %u -> method %u",
        sm_pairing_packet_get_io_capability(setup->sm_m_preq), sm_pairing_packet_get_io_capability(setup->sm_s_pres), setup->sm_stk_generation_method);
}

static int sm_key_distribution_flags_for_set(uint8_t key_set){
    int flags = 0;
    if (key_set & SM_KEYDIST_ENC_KEY){
        flags |= SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION;
        flags |= SM_KEYDIST_FLAG_MASTER_IDENTIFICATION;
    }
    if (key_set & SM_KEYDIST_ID_KEY){
        flags |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION;
        flags |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION;
    }
    if (key_set & SM_KEYDIST_SIGN){
        flags |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION;
    }
    return flags;
}

static void sm_setup_key_distribution(uint8_t keys_to_send, uint8_t keys_to_receive){
    setup->sm_key_distribution_received_set = 0;
    setup->sm_key_distribution_expected_set = sm_key_distribution_flags_for_set(keys_to_receive);
    setup->sm_key_distribution_send_set = sm_key_distribution_flags_for_set(keys_to_send);
    setup->sm_key_distribution_sent_set = 0;
#ifdef ENABLE_LE_SIGNED_WRITE
    setup->sm_le_device_index = -1;
#endif
}

// CSRK Key Lookup


static int sm_address_resolution_idle(void){
    return sm_address_resolution_mode == ADDRESS_RESOLUTION_IDLE;
}

static void sm_address_resolution_start_lookup(uint8_t addr_type, hci_con_handle_t con_handle, bd_addr_t addr, address_resolution_mode_t mode, void * context){
    (void)memcpy(sm_address_resolution_address, addr, 6);
    sm_address_resolution_addr_type = addr_type;
    sm_address_resolution_test = 0;
    sm_address_resolution_mode = mode;
    sm_address_resolution_context = context;
    sm_notify_client_base(SM_EVENT_IDENTITY_RESOLVING_STARTED, con_handle, addr_type, addr);
}

int sm_address_resolution_lookup(uint8_t address_type, bd_addr_t address){
    // check if already in list
    btstack_linked_list_iterator_t it;
    sm_lookup_entry_t * entry;
    btstack_linked_list_iterator_init(&it, &sm_address_resolution_general_queue);
    while(btstack_linked_list_iterator_has_next(&it)){
        entry = (sm_lookup_entry_t *) btstack_linked_list_iterator_next(&it);
        if (entry->address_type != address_type) continue;
        if (memcmp(entry->address, address, 6))  continue;
        // already in list
        return BTSTACK_BUSY;
    }
    entry = btstack_memory_sm_lookup_entry_get();
    if (!entry) return BTSTACK_MEMORY_ALLOC_FAILED;
    entry->address_type = (bd_addr_type_t) address_type;
    (void)memcpy(entry->address, address, 6);
    btstack_linked_list_add(&sm_address_resolution_general_queue, (btstack_linked_item_t *) entry);
    sm_trigger_run();
    return 0;
}

// CMAC calculation using AES Engineq
#ifdef USE_CMAC_ENGINE

static void sm_cmac_done_trampoline(void * arg){
    UNUSED(arg);
    sm_cmac_active = 0;
    (*sm_cmac_done_callback)(sm_cmac_hash);
    sm_trigger_run();
}

int sm_cmac_ready(void){
    return sm_cmac_active == 0u;
}
#endif

#ifdef ENABLE_LE_SECURE_CONNECTIONS
// generic cmac calculation
static void sm_cmac_message_start(const sm_key_t key, uint16_t message_len, const uint8_t * message, void (*done_callback)(uint8_t * hash)){
    sm_cmac_active = 1;
    sm_cmac_done_callback = done_callback;
    btstack_crypto_aes128_cmac_message(&sm_cmac_request, key, message_len, message, sm_cmac_hash, sm_cmac_done_trampoline, NULL);
}
#endif

// cmac for ATT Message signing
#ifdef ENABLE_LE_SIGNED_WRITE

static void sm_cmac_generator_start(const sm_key_t key, uint16_t message_len, uint8_t (*get_byte_callback)(uint16_t offset), void (*done_callback)(uint8_t * hash)){
    sm_cmac_active = 1;
    sm_cmac_done_callback = done_callback;
    btstack_crypto_aes128_cmac_generator(&sm_cmac_request, key, message_len, get_byte_callback, sm_cmac_hash, sm_cmac_done_trampoline, NULL);
}

static uint8_t sm_cmac_signed_write_message_get_byte(uint16_t offset){
    if (offset >= sm_cmac_signed_write_message_len) {
        log_error("sm_cmac_signed_write_message_get_byte. out of bounds, access %u, len %u", offset, sm_cmac_signed_write_message_len);
        return 0;
    }

    offset = sm_cmac_signed_write_message_len - 1 - offset;

    // sm_cmac_signed_write_header[3] | message[] | sm_cmac_signed_write_sign_counter[4]
    if (offset < 3){
        return sm_cmac_signed_write_header[offset];
    }
    int actual_message_len_incl_header = sm_cmac_signed_write_message_len - 4;
    if (offset <  actual_message_len_incl_header){
        return sm_cmac_signed_write_message[offset - 3];
    }
    return sm_cmac_signed_write_sign_counter[offset - actual_message_len_incl_header];
}

void sm_cmac_signed_write_start(const sm_key_t k, uint8_t opcode, hci_con_handle_t con_handle, uint16_t message_len, const uint8_t * message, uint32_t sign_counter, void (*done_handler)(uint8_t * hash)){
    // ATT Message Signing
    sm_cmac_signed_write_header[0] = opcode;
    little_endian_store_16(sm_cmac_signed_write_header, 1, con_handle);
    little_endian_store_32(sm_cmac_signed_write_sign_counter, 0, sign_counter);
    uint16_t total_message_len = 3 + message_len + 4;  // incl. virtually prepended att opcode, handle and appended sign_counter in LE
    sm_cmac_signed_write_message     = message;
    sm_cmac_signed_write_message_len = total_message_len;
    sm_cmac_generator_start(k, total_message_len, &sm_cmac_signed_write_message_get_byte, done_handler);
}
#endif

static void sm_trigger_user_response_basic(sm_connection_t * sm_conn, uint8_t event_type){
    setup->sm_user_response = SM_USER_RESPONSE_PENDING;
    uint8_t event[12];
    sm_setup_event_base(event, sizeof(event), event_type, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address);
    event[11] = setup->sm_use_secure_connections ? 1 : 0;
    sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event));
}

static void sm_trigger_user_response_passkey(sm_connection_t * sm_conn, uint8_t event_type){
    uint8_t event[16];
    uint32_t passkey = big_endian_read_32(setup->sm_tk, 12);
    sm_setup_event_base(event, sizeof(event), event_type, sm_conn->sm_handle,
                        sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address);
    event[11] = setup->sm_use_secure_connections ? 1 : 0;
    little_endian_store_32(event, 12, passkey);
    sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event));
}

static void sm_trigger_user_response(sm_connection_t * sm_conn){
    // notify client for: JUST WORKS confirm, Numeric comparison confirm, PASSKEY display or input
    setup->sm_user_response = SM_USER_RESPONSE_IDLE;
    sm_conn->sm_pairing_active = true;
    switch (setup->sm_stk_generation_method){
        case PK_RESP_INPUT:
            if (IS_RESPONDER(sm_conn->sm_role)){
                sm_trigger_user_response_basic(sm_conn, SM_EVENT_PASSKEY_INPUT_NUMBER);
            } else {
                sm_trigger_user_response_passkey(sm_conn, SM_EVENT_PASSKEY_DISPLAY_NUMBER);
            }
            break;
        case PK_INIT_INPUT:
            if (IS_RESPONDER(sm_conn->sm_role)){
                sm_trigger_user_response_passkey(sm_conn, SM_EVENT_PASSKEY_DISPLAY_NUMBER);
            } else {
                sm_trigger_user_response_basic(sm_conn, SM_EVENT_PASSKEY_INPUT_NUMBER);
            }
            break;
        case PK_BOTH_INPUT:
            sm_trigger_user_response_basic(sm_conn, SM_EVENT_PASSKEY_INPUT_NUMBER);
            break;
        case NUMERIC_COMPARISON:
            sm_trigger_user_response_passkey(sm_conn, SM_EVENT_NUMERIC_COMPARISON_REQUEST);
            break;
        case JUST_WORKS:
            sm_trigger_user_response_basic(sm_conn, SM_EVENT_JUST_WORKS_REQUEST);
            break;
        case OOB:
            // client already provided OOB data, let's skip notification.
            break;
        default:
            btstack_assert(false);
            break;
    }
}

static bool sm_key_distribution_all_received(void) {
    log_debug("sm_key_distribution_all_received: received 0x%02x, expecting 0x%02x", setup->sm_key_distribution_received_set, setup->sm_key_distribution_expected_set);
    return (setup->sm_key_distribution_expected_set & setup->sm_key_distribution_received_set) == setup->sm_key_distribution_expected_set;
}

static void sm_done_for_handle(hci_con_handle_t con_handle){
    if (sm_active_connection_handle == con_handle){
        sm_timeout_stop();
        sm_active_connection_handle = HCI_CON_HANDLE_INVALID;
        log_info("sm: connection 0x%x released setup context", con_handle);

#ifdef ENABLE_LE_SECURE_CONNECTIONS
        // generate new ec key after each pairing (that used it)
        if (setup->sm_use_secure_connections){
            sm_ec_generate_new_key();
        }
#endif
    }
}

static void sm_master_pairing_success(sm_connection_t *connection) {// master -> all done
    connection->sm_engine_state = SM_INITIATOR_CONNECTED;
    sm_pairing_complete(connection, ERROR_CODE_SUCCESS, 0);
    sm_done_for_handle(connection->sm_handle);
}

static int sm_key_distribution_flags_for_auth_req(void){

    int flags = SM_KEYDIST_ID_KEY;
    if (sm_auth_req & SM_AUTHREQ_BONDING){
        // encryption and signing information only if bonding requested
        flags |= SM_KEYDIST_ENC_KEY;
#ifdef ENABLE_LE_SIGNED_WRITE
        flags |= SM_KEYDIST_SIGN;
#endif
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
        // LinkKey for CTKD requires SC
        if (sm_auth_req & SM_AUTHREQ_SECURE_CONNECTION){
        	flags |= SM_KEYDIST_LINK_KEY;
        }
#endif
    }
    return flags;
}

static void sm_reset_setup(void){
    // fill in sm setup
    setup->sm_state_vars = 0;
    setup->sm_keypress_notification = 0;
    setup->sm_have_oob_data = 0;
    sm_reset_tk();
}

static void sm_init_setup(sm_connection_t * sm_conn){
    // fill in sm setup
    setup->sm_peer_addr_type = sm_conn->sm_peer_addr_type;
    (void)memcpy(setup->sm_peer_address, sm_conn->sm_peer_address, 6);

    // query client for Legacy Pairing OOB data
    if (sm_get_oob_data != NULL) {
        setup->sm_have_oob_data = (*sm_get_oob_data)(sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address, setup->sm_tk);
    }

    // if available and SC supported, also ask for SC OOB Data
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    memset(setup->sm_ra, 0, 16);
    memset(setup->sm_rb, 0, 16);
    if (setup->sm_have_oob_data && (sm_auth_req & SM_AUTHREQ_SECURE_CONNECTION)){
        if (sm_get_sc_oob_data != NULL){
            if (IS_RESPONDER(sm_conn->sm_role)){
                setup->sm_have_oob_data = (*sm_get_sc_oob_data)(
                    sm_conn->sm_peer_addr_type,
                    sm_conn->sm_peer_address,
                    setup->sm_peer_confirm,
                    setup->sm_ra);
            } else {
                setup->sm_have_oob_data = (*sm_get_sc_oob_data)(
                    sm_conn->sm_peer_addr_type,
                    sm_conn->sm_peer_address,
                    setup->sm_peer_confirm,
                    setup->sm_rb);
            }
        } else {
            setup->sm_have_oob_data = 0;
        }
    }
#endif

    sm_pairing_packet_t * local_packet;
    if (IS_RESPONDER(sm_conn->sm_role)){
        // slave
        local_packet = &setup->sm_s_pres;
        setup->sm_m_addr_type = sm_conn->sm_peer_addr_type;
        setup->sm_s_addr_type = sm_conn->sm_own_addr_type;
        (void)memcpy(setup->sm_m_address, sm_conn->sm_peer_address, 6);
        (void)memcpy(setup->sm_s_address, sm_conn->sm_own_address, 6);
    } else {
        // master
        local_packet = &setup->sm_m_preq;
        setup->sm_s_addr_type = sm_conn->sm_peer_addr_type;
        setup->sm_m_addr_type = sm_conn->sm_own_addr_type;
        (void)memcpy(setup->sm_s_address, sm_conn->sm_peer_address, 6);
        (void)memcpy(setup->sm_m_address, sm_conn->sm_own_address, 6);

        uint8_t key_distribution_flags = sm_key_distribution_flags_for_auth_req();
        sm_pairing_packet_set_initiator_key_distribution(setup->sm_m_preq, key_distribution_flags);
        sm_pairing_packet_set_responder_key_distribution(setup->sm_m_preq, key_distribution_flags);
    }

    uint8_t auth_req = sm_auth_req & ~SM_AUTHREQ_CT2;
    uint8_t max_encryption_key_size = sm_max_encryption_key_size;
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    // enable SC for SC only mode
    if (sm_sc_only_mode){
        auth_req |= SM_AUTHREQ_SECURE_CONNECTION;
        max_encryption_key_size = 16;
    }
#endif
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
	// set CT2 if SC + Bonding + CTKD
	const uint8_t auth_req_for_ct2 = SM_AUTHREQ_SECURE_CONNECTION | SM_AUTHREQ_BONDING;
	if ((auth_req & auth_req_for_ct2) == auth_req_for_ct2){
		auth_req |= SM_AUTHREQ_CT2;
	}
#endif
    sm_pairing_packet_set_io_capability(*local_packet, sm_io_capabilities);
    sm_pairing_packet_set_oob_data_flag(*local_packet, setup->sm_have_oob_data);
    sm_pairing_packet_set_auth_req(*local_packet, auth_req);
    sm_pairing_packet_set_max_encryption_key_size(*local_packet, max_encryption_key_size);
}

static int sm_stk_generation_init(sm_connection_t * sm_conn){

    sm_pairing_packet_t * remote_packet;
    uint8_t               keys_to_send;
    uint8_t               keys_to_receive;
    if (IS_RESPONDER(sm_conn->sm_role)){
        // slave / responder
        remote_packet   = &setup->sm_m_preq;
        keys_to_send    = sm_pairing_packet_get_responder_key_distribution(setup->sm_m_preq);
        keys_to_receive = sm_pairing_packet_get_initiator_key_distribution(setup->sm_m_preq);
    } else {
        // master / initiator
        remote_packet   = &setup->sm_s_pres;
        keys_to_send    = sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres);
        keys_to_receive = sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres);
    }

    // check key size
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    // SC Only mandates 128 bit key size
    if (sm_sc_only_mode && (sm_pairing_packet_get_max_encryption_key_size(*remote_packet) < 16)) {
        return SM_REASON_ENCRYPTION_KEY_SIZE;
    }
#endif
    sm_conn->sm_actual_encryption_key_size = sm_calc_actual_encryption_key_size(sm_pairing_packet_get_max_encryption_key_size(*remote_packet));
    if (sm_conn->sm_actual_encryption_key_size == 0u) return SM_REASON_ENCRYPTION_KEY_SIZE;

    // decide on STK generation method / SC
    sm_setup_tk();
    log_info("SMP: generation method %u", setup->sm_stk_generation_method);

    // check if STK generation method is acceptable by client
    if (!sm_validate_stk_generation_method()) return SM_REASON_AUTHENTHICATION_REQUIREMENTS;

#ifdef ENABLE_LE_SECURE_CONNECTIONS
    // Check LE SC Only mode
    if (sm_sc_only_mode && (setup->sm_use_secure_connections == false)){
        log_info("SC Only mode active but SC not possible");
        return SM_REASON_AUTHENTHICATION_REQUIREMENTS;
    }

    // LTK (= encryption information & master identification) only used exchanged for LE Legacy Connection
    if (setup->sm_use_secure_connections){
        keys_to_send &= ~SM_KEYDIST_ENC_KEY;
        keys_to_receive  &= ~SM_KEYDIST_ENC_KEY;
    }
#endif

    // identical to responder
    sm_setup_key_distribution(keys_to_send, keys_to_receive);

    // JUST WORKS doens't provide authentication
    sm_conn->sm_connection_authenticated = (setup->sm_stk_generation_method == JUST_WORKS) ? 0 : 1;

    return 0;
}

static void sm_address_resolution_handle_event(address_resolution_event_t event){

    // cache and reset context
    int matched_device_id = sm_address_resolution_test;
    address_resolution_mode_t mode = sm_address_resolution_mode;
    void * context = sm_address_resolution_context;

    // reset context
    sm_address_resolution_mode = ADDRESS_RESOLUTION_IDLE;
    sm_address_resolution_context = NULL;
    sm_address_resolution_test = -1;
    hci_con_handle_t con_handle = 0;

    sm_connection_t * sm_connection;
    sm_key_t ltk;
    bool have_ltk;
#ifdef ENABLE_LE_CENTRAL
    bool trigger_pairing;
    int authenticated;
#endif
    switch (mode){
        case ADDRESS_RESOLUTION_GENERAL:
            break;
        case ADDRESS_RESOLUTION_FOR_CONNECTION:
            sm_connection = (sm_connection_t *) context;
            con_handle = sm_connection->sm_handle;

            // have ltk -> start encryption / send security request
            // Core 5, Vol 3, Part C, 10.3.2 Initiating a Service Request
            // "When a bond has been created between two devices, any reconnection should result in the local device
            //  enabling or requesting encryption with the remote device before initiating any service request."

            switch (event){
                case ADDRESS_RESOLUTION_SUCCEEDED:
                    sm_connection->sm_irk_lookup_state = IRK_LOOKUP_SUCCEEDED;
                    sm_connection->sm_le_db_index = matched_device_id;
                    log_info("ADDRESS_RESOLUTION_SUCCEEDED, index %d", sm_connection->sm_le_db_index);

                    le_device_db_encryption_get(sm_connection->sm_le_db_index, NULL, NULL, ltk, NULL, &authenticated, NULL, NULL);
                    have_ltk = !sm_is_null_key(ltk);

                    if (sm_connection->sm_role) {
#ifdef ENABLE_LE_PERIPHERAL
                        // IRK required before, continue
                        if (sm_connection->sm_engine_state == SM_RESPONDER_PH0_RECEIVED_LTK_W4_IRK){
                            sm_connection->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST;
                            break;
                        }
                        if (sm_connection->sm_engine_state == SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED_W4_IRK){
                            sm_connection->sm_engine_state = SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED;
                            break;
                        }
                        bool trigger_security_request = (sm_connection->sm_pairing_requested != 0) || (sm_slave_request_security != 0);
                        sm_connection->sm_pairing_requested = 0;
#ifdef ENABLE_LE_PROACTIVE_AUTHENTICATION
                        // trigger security request for Proactive Authentication if LTK available
                        trigger_security_request = trigger_security_request || have_ltk;
#endif

                        log_info("peripheral: pairing request local %u, have_ltk %u => trigger_security_request %u",
                                 sm_connection->sm_pairing_requested, (int) have_ltk, trigger_security_request);

                        if (trigger_security_request){
                            sm_connection->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST;
                            if (have_ltk){
                                sm_reencryption_started(sm_connection);
                            } else {
                                sm_pairing_started(sm_connection);
                            }
                            sm_trigger_run();
                        }
#endif
                    } else {

#ifdef ENABLE_LE_CENTRAL
                        // check if pairing already requested and reset requests
                        trigger_pairing = sm_connection->sm_pairing_requested || sm_connection->sm_security_request_received;
                        bool auth_required = sm_auth_req & SM_AUTHREQ_MITM_PROTECTION;

                        log_info("central: pairing request local %u, remote %u => trigger_pairing %u. have_ltk %u",
                                 sm_connection->sm_pairing_requested, sm_connection->sm_security_request_received, (int) trigger_pairing, (int) have_ltk);
                        sm_connection->sm_security_request_received = 0;
                        sm_connection->sm_pairing_requested = 0;
                        bool trigger_reencryption = false;

                        if (have_ltk){
                            if (trigger_pairing){
                                // if pairing is requested, re-encryption is sufficient, if ltk is already authenticated or we don't require authentication
                                trigger_reencryption = (authenticated != 0) || (auth_required == false);
                            } else {
#ifdef ENABLE_LE_PROACTIVE_AUTHENTICATION
                                trigger_reencryption = true;
#else
                                log_info("central: defer enabling encryption for bonded device");
#endif
                            }
                        }

                        if (trigger_reencryption){
                            log_info("central: enable encryption for bonded device");
                            sm_connection->sm_engine_state = SM_INITIATOR_PH4_HAS_LTK;
                            break;
                        }

                        // pairing_request -> send pairing request
                        if (trigger_pairing){
                            sm_connection->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST;
                            break;
                        }
#endif
                    }
                    break;
                case ADDRESS_RESOLUTION_FAILED:
                    sm_connection->sm_irk_lookup_state = IRK_LOOKUP_FAILED;
                    if (sm_connection->sm_role) {
#ifdef ENABLE_LE_PERIPHERAL
                        // LTK request received before, IRK required -> negative LTK reply
                        if (sm_connection->sm_engine_state == SM_RESPONDER_PH0_RECEIVED_LTK_W4_IRK){
                            sm_connection->sm_engine_state = SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY;
                        }
                        // send security request if requested
                        bool trigger_security_request = (sm_connection->sm_pairing_requested != 0) || (sm_slave_request_security != 0);
                        sm_connection->sm_pairing_requested = 0;
                        if (trigger_security_request){
                            sm_connection->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST;
                            sm_pairing_started(sm_connection);
                        }
                        break;
#endif
                    }
#ifdef ENABLE_LE_CENTRAL
                    if (!sm_connection->sm_pairing_requested && !sm_connection->sm_security_request_received) break;
                    sm_connection->sm_security_request_received = 0;
                    sm_connection->sm_pairing_requested = 0;
                    sm_connection->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST;
#endif
                    break;

                default:
                    btstack_assert(false);
                    break;
            }
            break;
        default:
            break;
    }

    switch (event){
        case ADDRESS_RESOLUTION_SUCCEEDED:
            sm_notify_client_index(SM_EVENT_IDENTITY_RESOLVING_SUCCEEDED, con_handle, sm_address_resolution_addr_type, sm_address_resolution_address, matched_device_id);
            break;
        case ADDRESS_RESOLUTION_FAILED:
            sm_notify_client_base(SM_EVENT_IDENTITY_RESOLVING_FAILED, con_handle, sm_address_resolution_addr_type, sm_address_resolution_address);
            break;
        default:
            btstack_assert(false);
            break;
    }
}

static void sm_store_bonding_information(sm_connection_t * sm_conn){
    int le_db_index = -1;

    // lookup device based on IRK
    if (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_IDENTITY_INFORMATION){
        int i;
        for (i=0; i < le_device_db_max_count(); i++){
            sm_key_t irk;
            bd_addr_t address;
            int address_type = BD_ADDR_TYPE_UNKNOWN;
            le_device_db_info(i, &address_type, address, irk);
            // skip unused entries
            if (address_type == BD_ADDR_TYPE_UNKNOWN) continue;
            // compare Identity Address
            if (memcmp(address, setup->sm_peer_address, 6) != 0) continue;
            // compare Identity Resolving Key
            if (memcmp(irk, setup->sm_peer_irk, 16) != 0) continue;

            log_info("sm: device found for IRK, updating");
            le_db_index = i;
            break;
        }
    } else {
        // assert IRK is set to zero
        memset(setup->sm_peer_irk, 0, 16);
    }

    // if not found, lookup via public address if possible
    log_info("sm peer addr type %u, peer addres %s", setup->sm_peer_addr_type, bd_addr_to_str(setup->sm_peer_address));
    if ((le_db_index < 0) && (setup->sm_peer_addr_type == BD_ADDR_TYPE_LE_PUBLIC)){
        int i;
        for (i=0; i < le_device_db_max_count(); i++){
            bd_addr_t address;
            int address_type = BD_ADDR_TYPE_UNKNOWN;
            le_device_db_info(i, &address_type, address, NULL);
            // skip unused entries
            if (address_type == BD_ADDR_TYPE_UNKNOWN) continue;
            log_info("device %u, sm peer addr type %u, peer addres %s", i, address_type, bd_addr_to_str(address));
            if ((address_type == BD_ADDR_TYPE_LE_PUBLIC) && (memcmp(address, setup->sm_peer_address, 6) == 0)){
                log_info("sm: device found for public address, updating");
                le_db_index = i;
                break;
            }
        }
    }

    // if not found, add to db
    bool new_to_le_device_db = false;
    if (le_db_index < 0) {
        le_db_index = le_device_db_add(setup->sm_peer_addr_type, setup->sm_peer_address, setup->sm_peer_irk);
        new_to_le_device_db = true;
    }

    if (le_db_index >= 0){

#ifdef ENABLE_LE_PRIVACY_ADDRESS_RESOLUTION
        if (!new_to_le_device_db){
            hci_remove_le_device_db_entry_from_resolving_list(le_db_index);
        }
        hci_load_le_device_db_entry_into_resolving_list(le_db_index);
#else
        UNUSED(new_to_le_device_db);
#endif

        sm_notify_client_index(SM_EVENT_IDENTITY_CREATED, sm_conn->sm_handle, setup->sm_peer_addr_type, setup->sm_peer_address, le_db_index);
        sm_conn->sm_irk_lookup_state = IRK_LOOKUP_SUCCEEDED;
        sm_conn->sm_le_db_index = le_db_index;

#ifdef ENABLE_LE_SIGNED_WRITE
        // store local CSRK
        setup->sm_le_device_index = le_db_index;
        if ((setup->sm_key_distribution_sent_set) & SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION){
            log_info("sm: store local CSRK");
            le_device_db_local_csrk_set(le_db_index, setup->sm_local_csrk);
            le_device_db_local_counter_set(le_db_index, 0);
        }

        // store remote CSRK
        if (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION){
            log_info("sm: store remote CSRK");
            le_device_db_remote_csrk_set(le_db_index, setup->sm_peer_csrk);
            le_device_db_remote_counter_set(le_db_index, 0);
        }
#endif
        // store encryption information for secure connections: LTK generated by ECDH
        if (setup->sm_use_secure_connections){
            log_info("sm: store SC LTK (key size %u, authenticated %u)", sm_conn->sm_actual_encryption_key_size, sm_conn->sm_connection_authenticated);
            uint8_t zero_rand[8];
            memset(zero_rand, 0, 8);
            le_device_db_encryption_set(le_db_index, 0, zero_rand, setup->sm_ltk, sm_conn->sm_actual_encryption_key_size,
                                        sm_conn->sm_connection_authenticated, sm_conn->sm_connection_authorization_state == AUTHORIZATION_GRANTED, 1);
        }

        // store encryption information for legacy pairing: peer LTK, EDIV, RAND
        else if ( (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION)
        && (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_MASTER_IDENTIFICATION )){
            log_info("sm: set encryption information (key size %u, authenticated %u)", sm_conn->sm_actual_encryption_key_size, sm_conn->sm_connection_authenticated);
            le_device_db_encryption_set(le_db_index, setup->sm_peer_ediv, setup->sm_peer_rand, setup->sm_peer_ltk,
                                        sm_conn->sm_actual_encryption_key_size, sm_conn->sm_connection_authenticated, sm_conn->sm_connection_authorization_state == AUTHORIZATION_GRANTED, 0);

        }
    }
}

static void sm_pairing_error(sm_connection_t * sm_conn, uint8_t reason){
    sm_conn->sm_pairing_failed_reason = reason;
    sm_conn->sm_engine_state = SM_GENERAL_SEND_PAIRING_FAILED;
}

static int sm_le_device_db_index_lookup(bd_addr_type_t address_type, bd_addr_t address){
    int i;
    for (i=0; i < le_device_db_max_count(); i++){
        bd_addr_t db_address;
        int db_address_type = BD_ADDR_TYPE_UNKNOWN;
        le_device_db_info(i, &db_address_type, db_address, NULL);
        // skip unused entries
        if (address_type == BD_ADDR_TYPE_UNKNOWN) continue;
        if ((address_type == db_address_type) && (memcmp(address, db_address, 6) == 0)){
            return i;
        }
    }
    return -1;
}

static void sm_remove_le_device_db_entry(uint16_t i) {
    le_device_db_remove(i);
#ifdef ENABLE_LE_PRIVACY_ADDRESS_RESOLUTION
    // to remove an entry from the resolving list requires its identity address, which was already deleted
    // fully reload resolving list instead
    gap_load_resolving_list_from_le_device_db();
#endif
}

static uint8_t sm_key_distribution_validate_received(sm_connection_t * sm_conn){
    // if identity is provided, abort if we have bonding with same address but different irk
    if (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_IDENTITY_INFORMATION){
        int index = sm_le_device_db_index_lookup(BD_ADDR_TYPE_LE_PUBLIC, setup->sm_peer_address);
        if (index >= 0){
            sm_key_t irk;
            le_device_db_info(index, NULL, NULL, irk);
            if (memcmp(irk, setup->sm_peer_irk, 16) != 0){
                // IRK doesn't match, delete bonding information
                log_info("New IRK for %s (type %u) does not match stored IRK -> delete bonding information", bd_addr_to_str(sm_conn->sm_peer_address), sm_conn->sm_peer_addr_type);
                sm_remove_le_device_db_entry(index);
            }
        }
    }
    return 0;
}

static void sm_key_distribution_handle_all_received(sm_connection_t * sm_conn){

    // abort pairing if received keys are not valid
    uint8_t reason = sm_key_distribution_validate_received(sm_conn);
    if (reason != 0){
        sm_pairing_error(sm_conn, reason);
        return;
    }

    // only store pairing information if both sides are bondable, i.e., the bonadble flag is set
    bool bonding_enabled = (sm_pairing_packet_get_auth_req(setup->sm_m_preq)
                            & sm_pairing_packet_get_auth_req(setup->sm_s_pres)
                            & SM_AUTHREQ_BONDING ) != 0u;

    if (bonding_enabled){
        sm_store_bonding_information(sm_conn);
    } else {
        log_info("Ignoring received keys, bonding not enabled");
    }
}

static inline void sm_pdu_received_in_wrong_state(sm_connection_t * sm_conn){
    sm_pairing_error(sm_conn, SM_REASON_UNSPECIFIED_REASON);
}

#ifdef ENABLE_LE_SECURE_CONNECTIONS

static void sm_sc_prepare_dhkey_check(sm_connection_t * sm_conn);
static int sm_passkey_used(stk_generation_method_t method);
static int sm_just_works_or_numeric_comparison(stk_generation_method_t method);

static void sm_sc_start_calculating_local_confirm(sm_connection_t * sm_conn){
    if (setup->sm_stk_generation_method == OOB){
        sm_conn->sm_engine_state = SM_SC_W2_CMAC_FOR_CONFIRMATION;
    } else {
        btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_w2_cmac_for_confirmation, (void *)(uintptr_t) sm_conn->sm_handle);
    }
}

static void sm_sc_state_after_receiving_random(sm_connection_t * sm_conn){
    if (IS_RESPONDER(sm_conn->sm_role)){
        // Responder
        if (setup->sm_stk_generation_method == OOB){
            // generate Nb
            log_info("Generate Nb");
            btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_send_pairing_random, (void *)(uintptr_t) sm_conn->sm_handle);
        } else {
            sm_conn->sm_engine_state = SM_SC_SEND_PAIRING_RANDOM;
        }
    } else {
        // Initiator role
        switch (setup->sm_stk_generation_method){
            case JUST_WORKS:
                sm_sc_prepare_dhkey_check(sm_conn);
                break;

            case NUMERIC_COMPARISON:
                sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_G2;
                break;
            case PK_INIT_INPUT:
            case PK_RESP_INPUT:
            case PK_BOTH_INPUT:
                if (setup->sm_passkey_bit < 20u) {
                    sm_sc_start_calculating_local_confirm(sm_conn);
                } else {
                    sm_sc_prepare_dhkey_check(sm_conn);
                }
                break;
            case OOB:
                sm_sc_prepare_dhkey_check(sm_conn);
                break;
            default:
                btstack_assert(false);
                break;
        }
    }
}

static void sm_sc_cmac_done(uint8_t * hash){
    log_info("sm_sc_cmac_done: ");
    log_info_hexdump(hash, 16);

    if (sm_sc_oob_state == SM_SC_OOB_W4_CONFIRM){
        sm_sc_oob_state = SM_SC_OOB_IDLE;
        (*sm_sc_oob_callback)(hash, sm_sc_oob_random);
        return;
    }

    sm_connection_t * sm_conn = sm_cmac_connection;
    sm_cmac_connection = NULL;
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
    link_key_type_t link_key_type;
#endif

    switch (sm_conn->sm_engine_state){
        case SM_SC_W4_CMAC_FOR_CONFIRMATION:
            (void)memcpy(setup->sm_local_confirm, hash, 16);
            sm_conn->sm_engine_state = SM_SC_SEND_CONFIRMATION;
            break;
        case SM_SC_W4_CMAC_FOR_CHECK_CONFIRMATION:
            // check
            if (0 != memcmp(hash, setup->sm_peer_confirm, 16)){
                sm_pairing_error(sm_conn, SM_REASON_CONFIRM_VALUE_FAILED);
                break;
            }
            sm_sc_state_after_receiving_random(sm_conn);
            break;
        case SM_SC_W4_CALCULATE_G2: {
            uint32_t vab = big_endian_read_32(hash, 12) % 1000000;
            big_endian_store_32(setup->sm_tk, 12, vab);
            sm_conn->sm_engine_state = SM_SC_W4_USER_RESPONSE;
            sm_trigger_user_response(sm_conn);
            break;
        }
        case SM_SC_W4_CALCULATE_F5_SALT:
            (void)memcpy(setup->sm_t, hash, 16);
            sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_MACKEY;
            break;
        case SM_SC_W4_CALCULATE_F5_MACKEY:
            (void)memcpy(setup->sm_mackey, hash, 16);
            sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_LTK;
            break;
        case SM_SC_W4_CALCULATE_F5_LTK:
            // truncate sm_ltk, but keep full LTK for cross-transport key derivation in sm_local_ltk
            // Errata Service Release to the Bluetooth Specification: ESR09
            //   E6405 – Cross transport key derivation from a key of size less than 128 bits
            //   Note: When the BR/EDR link key is being derived from the LTK, the derivation is done before the LTK gets masked."
            (void)memcpy(setup->sm_ltk, hash, 16);
            (void)memcpy(setup->sm_local_ltk, hash, 16);
            sm_truncate_key(setup->sm_ltk, sm_conn->sm_actual_encryption_key_size);
            sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F6_FOR_DHKEY_CHECK;
            break;
        case SM_SC_W4_CALCULATE_F6_FOR_DHKEY_CHECK:
            (void)memcpy(setup->sm_local_dhkey_check, hash, 16);
            if (IS_RESPONDER(sm_conn->sm_role)){
                // responder
                if (setup->sm_state_vars & SM_STATE_VAR_DHKEY_COMMAND_RECEIVED){
                    sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK;
                } else {
                    sm_conn->sm_engine_state = SM_SC_W4_DHKEY_CHECK_COMMAND;
                }
            } else {
                sm_conn->sm_engine_state = SM_SC_SEND_DHKEY_CHECK_COMMAND;
            }
            break;
        case SM_SC_W4_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK:
            if (0 != memcmp(hash, setup->sm_peer_dhkey_check, 16) ){
                sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED);
                break;
            }
            if (IS_RESPONDER(sm_conn->sm_role)){
                // responder
                sm_conn->sm_engine_state = SM_SC_SEND_DHKEY_CHECK_COMMAND;
            } else {
                // initiator
                sm_conn->sm_engine_state = SM_INITIATOR_PH3_SEND_START_ENCRYPTION;
            }
            break;
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
        case SM_SC_W4_CALCULATE_ILK:
            (void)memcpy(setup->sm_t, hash, 16);
            sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_BR_EDR_LINK_KEY;
            break;
        case SM_SC_W4_CALCULATE_BR_EDR_LINK_KEY:
            reverse_128(hash, setup->sm_t);
            link_key_type = sm_conn->sm_connection_authenticated ?
                AUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256 : UNAUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256;
            log_info("Derived classic link key from LE using h6, type %u", (int) link_key_type);
			gap_store_link_key_for_bd_addr(setup->sm_peer_address, setup->sm_t, link_key_type);
            if (IS_RESPONDER(sm_conn->sm_role)){
                sm_conn->sm_engine_state = SM_RESPONDER_IDLE;
            } else {
                sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED;
            }
            sm_pairing_complete(sm_conn, ERROR_CODE_SUCCESS, 0);
            sm_done_for_handle(sm_conn->sm_handle);
            break;
        case SM_BR_EDR_W4_CALCULATE_ILK:
            (void)memcpy(setup->sm_t, hash, 16);
            sm_conn->sm_engine_state = SM_BR_EDR_W2_CALCULATE_LE_LTK;
            break;
        case SM_BR_EDR_W4_CALCULATE_LE_LTK:
            log_info("Derived LE LTK from BR/EDR Link Key");
            log_info_key("Link Key", hash);
            (void)memcpy(setup->sm_ltk, hash, 16);
            sm_truncate_key(setup->sm_ltk, sm_conn->sm_actual_encryption_key_size);
            sm_conn->sm_connection_authenticated = setup->sm_link_key_type == AUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256;
            sm_store_bonding_information(sm_conn);
            sm_done_for_handle(sm_conn->sm_handle);
            break;
#endif
        default:
            log_error("sm_sc_cmac_done in state %u", sm_conn->sm_engine_state);
            break;
    }
    sm_trigger_run();
}

static void f4_engine(sm_connection_t * sm_conn, const sm_key256_t u, const sm_key256_t v, const sm_key_t x, uint8_t z){
    const uint16_t message_len = 65;
    sm_cmac_connection = sm_conn;
    (void)memcpy(sm_cmac_sc_buffer, u, 32);
    (void)memcpy(sm_cmac_sc_buffer + 32, v, 32);
    sm_cmac_sc_buffer[64] = z;
    log_info("f4 key");
    log_info_hexdump(x, 16);
    log_info("f4 message");
    log_info_hexdump(sm_cmac_sc_buffer, message_len);
    sm_cmac_message_start(x, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}

static const uint8_t f5_key_id[] = { 0x62, 0x74, 0x6c, 0x65 };
static const uint8_t f5_length[] = { 0x01, 0x00};

static void f5_calculate_salt(sm_connection_t * sm_conn){

    static const sm_key_t f5_salt = { 0x6C ,0x88, 0x83, 0x91, 0xAA, 0xF5, 0xA5, 0x38, 0x60, 0x37, 0x0B, 0xDB, 0x5A, 0x60, 0x83, 0xBE};

    log_info("f5_calculate_salt");
    // calculate salt for f5
    const uint16_t message_len = 32;
    sm_cmac_connection = sm_conn;
    (void)memcpy(sm_cmac_sc_buffer, setup->sm_dhkey, message_len);
    sm_cmac_message_start(f5_salt, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}

static inline void f5_mackkey(sm_connection_t * sm_conn, sm_key_t t, const sm_key_t n1, const sm_key_t n2, const sm_key56_t a1, const sm_key56_t a2){
    const uint16_t message_len = 53;
    sm_cmac_connection = sm_conn;

    // f5(W, N1, N2, A1, A2) = AES-CMACT (Counter = 0 || keyID || N1 || N2|| A1|| A2 || Length = 256) -- this is the MacKey
    sm_cmac_sc_buffer[0] = 0;
    (void)memcpy(sm_cmac_sc_buffer + 01, f5_key_id, 4);
    (void)memcpy(sm_cmac_sc_buffer + 05, n1, 16);
    (void)memcpy(sm_cmac_sc_buffer + 21, n2, 16);
    (void)memcpy(sm_cmac_sc_buffer + 37, a1, 7);
    (void)memcpy(sm_cmac_sc_buffer + 44, a2, 7);
    (void)memcpy(sm_cmac_sc_buffer + 51, f5_length, 2);
    log_info("f5 key");
    log_info_hexdump(t, 16);
    log_info("f5 message for MacKey");
    log_info_hexdump(sm_cmac_sc_buffer, message_len);
    sm_cmac_message_start(t, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}

static void f5_calculate_mackey(sm_connection_t * sm_conn){
    sm_key56_t bd_addr_master, bd_addr_slave;
    bd_addr_master[0] =  setup->sm_m_addr_type;
    bd_addr_slave[0]  =  setup->sm_s_addr_type;
    (void)memcpy(&bd_addr_master[1], setup->sm_m_address, 6);
    (void)memcpy(&bd_addr_slave[1], setup->sm_s_address, 6);
    if (IS_RESPONDER(sm_conn->sm_role)){
        // responder
        f5_mackkey(sm_conn, setup->sm_t, setup->sm_peer_nonce, setup->sm_local_nonce, bd_addr_master, bd_addr_slave);
    } else {
        // initiator
        f5_mackkey(sm_conn, setup->sm_t, setup->sm_local_nonce, setup->sm_peer_nonce, bd_addr_master, bd_addr_slave);
    }
}

// note: must be called right after f5_mackey, as sm_cmac_buffer[1..52] will be reused
static inline void f5_ltk(sm_connection_t * sm_conn, sm_key_t t){
    const uint16_t message_len = 53;
    sm_cmac_connection = sm_conn;
    sm_cmac_sc_buffer[0] = 1;
    // 1..52 setup before
    log_info("f5 key");
    log_info_hexdump(t, 16);
    log_info("f5 message for LTK");
    log_info_hexdump(sm_cmac_sc_buffer, message_len);
    sm_cmac_message_start(t, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}

static void f5_calculate_ltk(sm_connection_t * sm_conn){
    f5_ltk(sm_conn, setup->sm_t);
}

static void f6_setup(const sm_key_t n1, const sm_key_t n2, const sm_key_t r, const sm_key24_t io_cap, const sm_key56_t a1, const sm_key56_t a2){
    (void)memcpy(sm_cmac_sc_buffer, n1, 16);
    (void)memcpy(sm_cmac_sc_buffer + 16, n2, 16);
    (void)memcpy(sm_cmac_sc_buffer + 32, r, 16);
    (void)memcpy(sm_cmac_sc_buffer + 48, io_cap, 3);
    (void)memcpy(sm_cmac_sc_buffer + 51, a1, 7);
    (void)memcpy(sm_cmac_sc_buffer + 58, a2, 7);
}

static void f6_engine(sm_connection_t * sm_conn, const sm_key_t w){
    const uint16_t message_len = 65;
    sm_cmac_connection = sm_conn;
    log_info("f6 key");
    log_info_hexdump(w, 16);
    log_info("f6 message");
    log_info_hexdump(sm_cmac_sc_buffer, message_len);
    sm_cmac_message_start(w, 65, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}

// g2(U, V, X, Y) = AES-CMACX(U || V || Y) mod 2^32
// - U is 256 bits
// - V is 256 bits
// - X is 128 bits
// - Y is 128 bits
static void g2_engine(sm_connection_t * sm_conn, const sm_key256_t u, const sm_key256_t v, const sm_key_t x, const sm_key_t y){
    const uint16_t message_len = 80;
    sm_cmac_connection = sm_conn;
    (void)memcpy(sm_cmac_sc_buffer, u, 32);
    (void)memcpy(sm_cmac_sc_buffer + 32, v, 32);
    (void)memcpy(sm_cmac_sc_buffer + 64, y, 16);
    log_info("g2 key");
    log_info_hexdump(x, 16);
    log_info("g2 message");
    log_info_hexdump(sm_cmac_sc_buffer, message_len);
    sm_cmac_message_start(x, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}

static void g2_calculate(sm_connection_t * sm_conn) {
    // calc Va if numeric comparison
    if (IS_RESPONDER(sm_conn->sm_role)){
        // responder
        g2_engine(sm_conn, setup->sm_peer_q, ec_q, setup->sm_peer_nonce, setup->sm_local_nonce);;
    } else {
        // initiator
        g2_engine(sm_conn, ec_q, setup->sm_peer_q, setup->sm_local_nonce, setup->sm_peer_nonce);
    }
}

static void sm_sc_calculate_local_confirm(sm_connection_t * sm_conn){
    uint8_t z = 0;
    if (sm_passkey_entry(setup->sm_stk_generation_method)){
        // some form of passkey
        uint32_t pk = big_endian_read_32(setup->sm_tk, 12);
        z = 0x80u | ((pk >> setup->sm_passkey_bit) & 1u);
        setup->sm_passkey_bit++;
    }
    f4_engine(sm_conn, ec_q, setup->sm_peer_q, setup->sm_local_nonce, z);
}

static void sm_sc_calculate_remote_confirm(sm_connection_t * sm_conn){
    // OOB
    if (setup->sm_stk_generation_method == OOB){
        if (IS_RESPONDER(sm_conn->sm_role)){
            f4_engine(sm_conn, setup->sm_peer_q, setup->sm_peer_q, setup->sm_ra, 0);
        } else {
            f4_engine(sm_conn, setup->sm_peer_q, setup->sm_peer_q, setup->sm_rb, 0);
        }
        return;
    }

    uint8_t z = 0;
    if (sm_passkey_entry(setup->sm_stk_generation_method)){
        // some form of passkey
        uint32_t pk = big_endian_read_32(setup->sm_tk, 12);
        // sm_passkey_bit was increased before sending confirm value
        z = 0x80u | ((pk >> (setup->sm_passkey_bit-1u)) & 1u);
    }
    f4_engine(sm_conn, setup->sm_peer_q, ec_q, setup->sm_peer_nonce, z);
}

static void sm_sc_prepare_dhkey_check(sm_connection_t * sm_conn){
    log_info("sm_sc_prepare_dhkey_check, DHKEY calculated %u", (setup->sm_state_vars & SM_STATE_VAR_DHKEY_CALCULATED) ? 1 : 0);

    if (setup->sm_state_vars & SM_STATE_VAR_DHKEY_CALCULATED){
        sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_SALT;
        return;
    } else {
        sm_conn->sm_engine_state = SM_SC_W4_CALCULATE_DHKEY;
    }
}

static void sm_sc_dhkey_calculated(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (sm_conn == NULL) return;

    log_info("dhkey");
    log_info_hexdump(&setup->sm_dhkey[0], 32);
    setup->sm_state_vars |= SM_STATE_VAR_DHKEY_CALCULATED;
    // trigger next step
    if (sm_conn->sm_engine_state == SM_SC_W4_CALCULATE_DHKEY){
        sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_SALT;
    }
    sm_trigger_run();
}

static void sm_sc_calculate_f6_for_dhkey_check(sm_connection_t * sm_conn){
    // calculate DHKCheck
    sm_key56_t bd_addr_master, bd_addr_slave;
    bd_addr_master[0] =  setup->sm_m_addr_type;
    bd_addr_slave[0]  =  setup->sm_s_addr_type;
    (void)memcpy(&bd_addr_master[1], setup->sm_m_address, 6);
    (void)memcpy(&bd_addr_slave[1], setup->sm_s_address, 6);
    uint8_t iocap_a[3];
    iocap_a[0] = sm_pairing_packet_get_auth_req(setup->sm_m_preq);
    iocap_a[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq);
    iocap_a[2] = sm_pairing_packet_get_io_capability(setup->sm_m_preq);
    uint8_t iocap_b[3];
    iocap_b[0] = sm_pairing_packet_get_auth_req(setup->sm_s_pres);
    iocap_b[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres);
    iocap_b[2] = sm_pairing_packet_get_io_capability(setup->sm_s_pres);
    if (IS_RESPONDER(sm_conn->sm_role)){
        // responder
        f6_setup(setup->sm_local_nonce, setup->sm_peer_nonce, setup->sm_ra, iocap_b, bd_addr_slave, bd_addr_master);
        f6_engine(sm_conn, setup->sm_mackey);
    } else {
        // initiator
        f6_setup( setup->sm_local_nonce, setup->sm_peer_nonce, setup->sm_rb, iocap_a, bd_addr_master, bd_addr_slave);
        f6_engine(sm_conn, setup->sm_mackey);
    }
}

static void sm_sc_calculate_f6_to_verify_dhkey_check(sm_connection_t * sm_conn){
    // validate E = f6()
    sm_key56_t bd_addr_master, bd_addr_slave;
    bd_addr_master[0] =  setup->sm_m_addr_type;
    bd_addr_slave[0]  =  setup->sm_s_addr_type;
    (void)memcpy(&bd_addr_master[1], setup->sm_m_address, 6);
    (void)memcpy(&bd_addr_slave[1], setup->sm_s_address, 6);

    uint8_t iocap_a[3];
    iocap_a[0] = sm_pairing_packet_get_auth_req(setup->sm_m_preq);
    iocap_a[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq);
    iocap_a[2] = sm_pairing_packet_get_io_capability(setup->sm_m_preq);
    uint8_t iocap_b[3];
    iocap_b[0] = sm_pairing_packet_get_auth_req(setup->sm_s_pres);
    iocap_b[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres);
    iocap_b[2] = sm_pairing_packet_get_io_capability(setup->sm_s_pres);
    if (IS_RESPONDER(sm_conn->sm_role)){
        // responder
        f6_setup(setup->sm_peer_nonce, setup->sm_local_nonce, setup->sm_rb, iocap_a, bd_addr_master, bd_addr_slave);
        f6_engine(sm_conn, setup->sm_mackey);
    } else {
        // initiator
        f6_setup(setup->sm_peer_nonce, setup->sm_local_nonce, setup->sm_ra, iocap_b, bd_addr_slave, bd_addr_master);
        f6_engine(sm_conn, setup->sm_mackey);
    }
}

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION

//
// Link Key Conversion Function h6
//
// h6(W, keyID) = AES-CMAC_W(keyID)
// - W is 128 bits
// - keyID is 32 bits
static void h6_engine(sm_connection_t * sm_conn, const sm_key_t w, const uint32_t key_id){
    const uint16_t message_len = 4;
    sm_cmac_connection = sm_conn;
    big_endian_store_32(sm_cmac_sc_buffer, 0, key_id);
    log_info("h6 key");
    log_info_hexdump(w, 16);
    log_info("h6 message");
    log_info_hexdump(sm_cmac_sc_buffer, message_len);
    sm_cmac_message_start(w, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done);
}
//
// Link Key Conversion Function h7
//
// h7(SALT, W) = AES-CMAC_SALT(W)
// - SALT is 128 bits
// - W    is 128 bits
static void h7_engine(sm_connection_t * sm_conn, const sm_key_t salt, const sm_key_t w) {
	const uint16_t message_len = 16;
	sm_cmac_connection = sm_conn;
	log_info("h7 key");
	log_info_hexdump(salt, 16);
	log_info("h7 message");
	log_info_hexdump(w, 16);
	sm_cmac_message_start(salt, message_len, w, &sm_sc_cmac_done);
}

// For SC, setup->sm_local_ltk holds full LTK (sm_ltk is already truncated)
// Errata Service Release to the Bluetooth Specification: ESR09
//   E6405 – Cross transport key derivation from a key of size less than 128 bits
//   "Note: When the BR/EDR link key is being derived from the LTK, the derivation is done before the LTK gets masked."

static void h6_calculate_ilk_from_le_ltk(sm_connection_t * sm_conn){
    h6_engine(sm_conn, setup->sm_local_ltk, 0x746D7031);    // "tmp1"
}

static void h6_calculate_ilk_from_br_edr(sm_connection_t * sm_conn){
    h6_engine(sm_conn, setup->sm_link_key, 0x746D7032);    // "tmp2"
}

static void h6_calculate_br_edr_link_key(sm_connection_t * sm_conn){
    h6_engine(sm_conn, setup->sm_t, 0x6c656272);    // "lebr"
}

static void h6_calculate_le_ltk(sm_connection_t * sm_conn){
    h6_engine(sm_conn, setup->sm_t, 0x62726C65);    // "brle"
}

static void h7_calculate_ilk_from_le_ltk(sm_connection_t * sm_conn){
	const uint8_t salt[16] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,  0x00, 0x00, 0x00, 0x00, 0x74, 0x6D, 0x70, 0x31};  // "tmp1"
	h7_engine(sm_conn, salt, setup->sm_local_ltk);
}

static void h7_calculate_ilk_from_br_edr(sm_connection_t * sm_conn){
    const uint8_t salt[16] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,  0x00, 0x00, 0x00, 0x00, 0x74, 0x6D, 0x70, 0x32};  // "tmp2"
    h7_engine(sm_conn, salt, setup->sm_link_key);
}

static void sm_ctkd_fetch_br_edr_link_key(sm_connection_t * sm_conn){
    hci_connection_t * hci_connection = hci_connection_for_handle(sm_conn->sm_handle);
    btstack_assert(hci_connection != NULL);
    reverse_128(hci_connection->link_key, setup->sm_link_key);
    setup->sm_link_key_type =  hci_connection->link_key_type;
}

static void sm_ctkd_start_from_br_edr(sm_connection_t * sm_conn){
    // only derive LTK if EncKey is set by both
    bool derive_ltk = (sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres) &
                              sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres) & SM_KEYDIST_ENC_KEY) != 0;
    if (derive_ltk){
        bool use_h7 = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_CT2) != 0;
        sm_conn->sm_engine_state = use_h7 ? SM_BR_EDR_W2_CALCULATE_ILK_USING_H7 : SM_BR_EDR_W2_CALCULATE_ILK_USING_H6;
    } else {
        sm_done_for_handle(sm_conn->sm_handle);
    }
}

#endif

#endif

// key management legacy connections:
// - potentially two different LTKs based on direction. each device stores LTK provided by peer
// - master stores LTK, EDIV, RAND. responder optionally stored master LTK (only if it needs to reconnect)
// - initiators reconnects: initiator uses stored LTK, EDIV, RAND generated by responder
// - responder  reconnects: responder uses LTK receveived from master

// key management secure connections:
// - both devices store same LTK from ECDH key exchange.

#if defined(ENABLE_LE_SECURE_CONNECTIONS) || defined(ENABLE_LE_CENTRAL)
static void sm_load_security_info(sm_connection_t * sm_connection){
    int encryption_key_size;
    int authenticated;
    int authorized;
    int secure_connection;

    // fetch data from device db - incl. authenticated/authorized/key size. Note all sm_connection_X require encryption enabled
    le_device_db_encryption_get(sm_connection->sm_le_db_index, &setup->sm_peer_ediv, setup->sm_peer_rand, setup->sm_peer_ltk,
                                &encryption_key_size, &authenticated, &authorized, &secure_connection);
    log_info("db index %u, key size %u, authenticated %u, authorized %u, secure connetion %u", sm_connection->sm_le_db_index, encryption_key_size, authenticated, authorized, secure_connection);
    sm_connection->sm_actual_encryption_key_size = encryption_key_size;
    sm_connection->sm_connection_authenticated = authenticated;
    sm_connection->sm_connection_authorization_state = authorized ? AUTHORIZATION_GRANTED : AUTHORIZATION_UNKNOWN;
    sm_connection->sm_connection_sc = secure_connection;
}
#endif

#ifdef ENABLE_LE_PERIPHERAL
static void sm_start_calculating_ltk_from_ediv_and_rand(sm_connection_t * sm_connection){
    (void)memcpy(setup->sm_local_rand, sm_connection->sm_local_rand, 8);
    setup->sm_local_ediv = sm_connection->sm_local_ediv;
    // re-establish used key encryption size
    // no db for encryption size hack: encryption size is stored in lowest nibble of setup->sm_local_rand
    sm_connection->sm_actual_encryption_key_size = (setup->sm_local_rand[7u] & 0x0fu) + 1u;
    // no db for authenticated flag hack: flag is stored in bit 4 of LSB
    sm_connection->sm_connection_authenticated = (setup->sm_local_rand[7u] & 0x10u) >> 4u;
    // Legacy paring -> not SC
    sm_connection->sm_connection_sc = 0;
    log_info("sm: received ltk request with key size %u, authenticated %u",
            sm_connection->sm_actual_encryption_key_size, sm_connection->sm_connection_authenticated);
}
#endif

// distributed key generation
static bool sm_run_dpkg(void){
    switch (dkg_state){
        case DKG_CALC_IRK:
            // already busy?
            if (sm_aes128_state == SM_AES128_IDLE) {
                log_info("DKG_CALC_IRK started");
                // IRK = d1(IR, 1, 0)
                sm_d1_d_prime(1, 0, sm_aes128_plaintext);  // plaintext = d1 prime
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_ir, sm_aes128_plaintext, sm_persistent_irk, sm_handle_encryption_result_dkg_irk, NULL);
                return true;
            }
            break;
        case DKG_CALC_DHK:
            // already busy?
            if (sm_aes128_state == SM_AES128_IDLE) {
                log_info("DKG_CALC_DHK started");
                // DHK = d1(IR, 3, 0)
                sm_d1_d_prime(3, 0, sm_aes128_plaintext);  // plaintext = d1 prime
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_ir, sm_aes128_plaintext, sm_persistent_dhk, sm_handle_encryption_result_dkg_dhk, NULL);
                return true;
            }
            break;
        default:
            break;
    }
    return false;
}

// random address updates
static bool sm_run_rau(void){
    switch (rau_state){
        case RAU_GET_RANDOM:
            rau_state = RAU_W4_RANDOM;
            btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_address, 6, &sm_handle_random_result_rau, NULL);
            return true;
        case RAU_GET_ENC:
            // already busy?
            if (sm_aes128_state == SM_AES128_IDLE) {
                sm_ah_r_prime(sm_random_address, sm_aes128_plaintext);
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_irk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_rau, NULL);
                return true;
            }
            break;
        default:
            break;
    }
    return false;
}

// CSRK Lookup
static bool sm_run_csrk(void){
    btstack_linked_list_iterator_t it;

    // -- if csrk lookup ready, find connection that require csrk lookup
    if (sm_address_resolution_idle()){
        hci_connections_get_iterator(&it);
        while(btstack_linked_list_iterator_has_next(&it)){
            hci_connection_t * hci_connection = (hci_connection_t *) btstack_linked_list_iterator_next(&it);
            sm_connection_t  * sm_connection  = &hci_connection->sm_connection;
            if (sm_connection->sm_irk_lookup_state == IRK_LOOKUP_W4_READY){
                // and start lookup
                sm_address_resolution_start_lookup(sm_connection->sm_peer_addr_type, sm_connection->sm_handle, sm_connection->sm_peer_address, ADDRESS_RESOLUTION_FOR_CONNECTION, sm_connection);
                sm_connection->sm_irk_lookup_state = IRK_LOOKUP_STARTED;
                break;
            }
        }
    }

    // -- if csrk lookup ready, resolved addresses for received addresses
    if (sm_address_resolution_idle()) {
        if (!btstack_linked_list_empty(&sm_address_resolution_general_queue)){
            sm_lookup_entry_t * entry = (sm_lookup_entry_t *) sm_address_resolution_general_queue;
            btstack_linked_list_remove(&sm_address_resolution_general_queue, (btstack_linked_item_t *) entry);
            sm_address_resolution_start_lookup(entry->address_type, 0, entry->address, ADDRESS_RESOLUTION_GENERAL, NULL);
            btstack_memory_sm_lookup_entry_free(entry);
        }
    }

    // -- Continue with device lookup by public or resolvable private address
    if (!sm_address_resolution_idle()){
        while (sm_address_resolution_test < le_device_db_max_count()){
            int addr_type = BD_ADDR_TYPE_UNKNOWN;
            bd_addr_t addr;
            sm_key_t irk;
            le_device_db_info(sm_address_resolution_test, &addr_type, addr, irk);

            // skip unused entries
            if (addr_type == BD_ADDR_TYPE_UNKNOWN){
                sm_address_resolution_test++;
                continue;
            }

            log_info("LE Device Lookup: device %u of %u", sm_address_resolution_test, le_device_db_max_count());

            if ((sm_address_resolution_addr_type == addr_type) && (memcmp(addr, sm_address_resolution_address, 6) == 0)){
                log_info("LE Device Lookup: found by { addr_type, address} ");
                sm_address_resolution_handle_event(ADDRESS_RESOLUTION_SUCCEEDED);
                break;
            }

            // if connection type is public, it must be a different one
            if (sm_address_resolution_addr_type == BD_ADDR_TYPE_LE_PUBLIC){
                sm_address_resolution_test++;
                continue;
            }

            // skip AH if no IRK
            if (sm_is_null_key(irk)){
                sm_address_resolution_test++;
                continue;
            }

            if (sm_aes128_state == SM_AES128_ACTIVE) break;

            log_info("LE Device Lookup: calculate AH");
            log_info_key("IRK", irk);

            (void)memcpy(sm_aes128_key, irk, 16);
            sm_ah_r_prime(sm_address_resolution_address, sm_aes128_plaintext);
            sm_aes128_state = SM_AES128_ACTIVE;
            btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_aes128_key, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_address_resolution, NULL);
            return true;
        }

        if (sm_address_resolution_test >= le_device_db_max_count()){
            log_info("LE Device Lookup: not found");
            sm_address_resolution_handle_event(ADDRESS_RESOLUTION_FAILED);
        }
    }
    return false;
}

// SC OOB
static bool sm_run_oob(void){
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    switch (sm_sc_oob_state){
        case SM_SC_OOB_W2_CALC_CONFIRM:
            if (!sm_cmac_ready()) break;
            sm_sc_oob_state = SM_SC_OOB_W4_CONFIRM;
            f4_engine(NULL, ec_q, ec_q, sm_sc_oob_random, 0);
            return true;
        default:
            break;
    }
#endif
    return false;
}

static void sm_send_connectionless(sm_connection_t * sm_connection, const uint8_t * buffer, uint16_t size){
    l2cap_send_connectionless(sm_connection->sm_handle, sm_connection->sm_cid, (uint8_t*) buffer, size);
}

// handle basic actions that don't requires the full context
static bool sm_run_basic(void){
    btstack_linked_list_iterator_t it;
    hci_connections_get_iterator(&it);
    while(btstack_linked_list_iterator_has_next(&it)){
        hci_connection_t * hci_connection = (hci_connection_t *) btstack_linked_list_iterator_next(&it);
        sm_connection_t  * sm_connection = &hci_connection->sm_connection;
        switch(sm_connection->sm_engine_state){

            // general
            case SM_GENERAL_SEND_PAIRING_FAILED: {
                uint8_t buffer[2];
                buffer[0] = SM_CODE_PAIRING_FAILED;
                buffer[1] = sm_connection->sm_pairing_failed_reason;
                sm_connection->sm_engine_state = sm_connection->sm_role ? SM_RESPONDER_IDLE : SM_INITIATOR_CONNECTED;
                sm_send_connectionless(sm_connection, (uint8_t*) buffer, sizeof(buffer));
                sm_pairing_complete(sm_connection, ERROR_CODE_AUTHENTICATION_FAILURE, sm_connection->sm_pairing_failed_reason);
                sm_done_for_handle(sm_connection->sm_handle);
                break;
            }

            // responder side
            case SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY:
                sm_connection->sm_engine_state = SM_RESPONDER_IDLE;
                hci_send_cmd(&hci_le_long_term_key_negative_reply, sm_connection->sm_handle);
                return true;

#ifdef ENABLE_LE_SECURE_CONNECTIONS
            case SM_SC_RECEIVED_LTK_REQUEST:
                switch (sm_connection->sm_irk_lookup_state){
                    case IRK_LOOKUP_FAILED:
                        log_info("LTK Request: IRK Lookup Failed)");
                        sm_connection->sm_engine_state = SM_RESPONDER_IDLE;
                        hci_send_cmd(&hci_le_long_term_key_negative_reply, sm_connection->sm_handle);
                        return true;
                    default:
                        break;
                }
                break;
#endif
            default:
                break;
        }
    }
    return false;
}

static void sm_run_activate_connection(void){
    // Find connections that requires setup context and make active if no other is locked
    btstack_linked_list_iterator_t it;
    hci_connections_get_iterator(&it);
    while((sm_active_connection_handle == HCI_CON_HANDLE_INVALID) && btstack_linked_list_iterator_has_next(&it)){
        hci_connection_t * hci_connection = (hci_connection_t *) btstack_linked_list_iterator_next(&it);
        sm_connection_t  * sm_connection = &hci_connection->sm_connection;
        // - if no connection locked and we're ready/waiting for setup context, fetch it and start
        bool done = true;
        int err;
        UNUSED(err);

#ifdef ENABLE_LE_SECURE_CONNECTIONS
        // assert ec key is ready
        if (   (sm_connection->sm_engine_state == SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED)
            || (sm_connection->sm_engine_state == SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST)
			|| (sm_connection->sm_engine_state == SM_RESPONDER_SEND_SECURITY_REQUEST)){
            if (ec_key_generation_state == EC_KEY_GENERATION_IDLE){
                sm_ec_generate_new_key();
            }
            if (ec_key_generation_state != EC_KEY_GENERATION_DONE){
                continue;
            }
        }
#endif

        switch (sm_connection->sm_engine_state) {
#ifdef ENABLE_LE_PERIPHERAL
            case SM_RESPONDER_SEND_SECURITY_REQUEST:
            case SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED:
            case SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST:
#ifdef ENABLE_LE_SECURE_CONNECTIONS
            case SM_SC_RECEIVED_LTK_REQUEST:
#endif
#endif
#ifdef ENABLE_LE_CENTRAL
            case SM_INITIATOR_PH4_HAS_LTK:
			case SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST:
#endif
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
            case SM_BR_EDR_RESPONDER_PAIRING_REQUEST_RECEIVED:
            case SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST:
#endif
				// just lock context
				break;
            default:
                done = false;
                break;
        }
        if (done){
            sm_active_connection_handle = sm_connection->sm_handle;
            log_info("sm: connection 0x%04x locked setup context as %s, state %u", sm_active_connection_handle, sm_connection->sm_role ? "responder" : "initiator", sm_connection->sm_engine_state);
        }
    }
}

static void sm_run_send_keypress_notification(sm_connection_t * connection){
    int i;
    uint8_t flags       = setup->sm_keypress_notification & 0x1fu;
    uint8_t num_actions = setup->sm_keypress_notification >> 5;
    uint8_t action = 0;
    for (i=SM_KEYPRESS_PASSKEY_ENTRY_STARTED;i<=SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED;i++){
        if (flags & (1u<<i)){
            bool clear_flag = true;
            switch (i){
                case SM_KEYPRESS_PASSKEY_ENTRY_STARTED:
                case SM_KEYPRESS_PASSKEY_CLEARED:
                case SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED:
                default:
                    break;
                case SM_KEYPRESS_PASSKEY_DIGIT_ENTERED:
                case SM_KEYPRESS_PASSKEY_DIGIT_ERASED:
                    num_actions--;
                    clear_flag = num_actions == 0u;
                    break;
            }
            if (clear_flag){
                flags &= ~(1<<i);
            }
            action = i;
            break;
        }
    }
    setup->sm_keypress_notification = (num_actions << 5) | flags;

    // send keypress notification
    uint8_t buffer[2];
    buffer[0] = SM_CODE_KEYPRESS_NOTIFICATION;
    buffer[1] = action;
    sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));

    // try
    l2cap_request_can_send_fix_channel_now_event(sm_active_connection_handle, connection->sm_cid);
}

static void sm_run_distribute_keys(sm_connection_t * connection){
    if (setup->sm_key_distribution_send_set &   SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION){
        setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION;
        setup->sm_key_distribution_sent_set |=  SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION;
        uint8_t buffer[17];
        buffer[0] = SM_CODE_ENCRYPTION_INFORMATION;
        reverse_128(setup->sm_ltk, &buffer[1]);
        sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
        sm_timeout_reset(connection);
        return;
    }
    if (setup->sm_key_distribution_send_set &   SM_KEYDIST_FLAG_MASTER_IDENTIFICATION){
        setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_MASTER_IDENTIFICATION;
        setup->sm_key_distribution_sent_set |=  SM_KEYDIST_FLAG_MASTER_IDENTIFICATION;
        uint8_t buffer[11];
        buffer[0] = SM_CODE_MASTER_IDENTIFICATION;
        little_endian_store_16(buffer, 1, setup->sm_local_ediv);
        reverse_64(setup->sm_local_rand, &buffer[3]);
        sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
        sm_timeout_reset(connection);
        return;
    }
    if (setup->sm_key_distribution_send_set &   SM_KEYDIST_FLAG_IDENTITY_INFORMATION){
        setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_IDENTITY_INFORMATION;
        setup->sm_key_distribution_sent_set |=  SM_KEYDIST_FLAG_IDENTITY_INFORMATION;
        uint8_t buffer[17];
        buffer[0] = SM_CODE_IDENTITY_INFORMATION;
        reverse_128(sm_persistent_irk, &buffer[1]);
        sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
        sm_timeout_reset(connection);
        return;
    }
    if (setup->sm_key_distribution_send_set &   SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION){
        setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION;
        setup->sm_key_distribution_sent_set |=  SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION;
        bd_addr_t local_address;
        uint8_t buffer[8];
        buffer[0] = SM_CODE_IDENTITY_ADDRESS_INFORMATION;
        switch (gap_random_address_get_mode()){
            case GAP_RANDOM_ADDRESS_TYPE_OFF:
            case GAP_RANDOM_ADDRESS_TYPE_STATIC:
                // public or static random
                gap_le_get_own_address(&buffer[1], local_address);
                break;
            case GAP_RANDOM_ADDRESS_NON_RESOLVABLE:
            case GAP_RANDOM_ADDRESS_RESOLVABLE:
                // fallback to public
                gap_local_bd_addr(local_address);
                buffer[1] = 0;
                break;
            default:
                btstack_assert(false);
                break;
        }
        reverse_bd_addr(local_address, &buffer[2]);
        sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
        sm_timeout_reset(connection);
        return;
    }
    if (setup->sm_key_distribution_send_set &   SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION){
        setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION;
        setup->sm_key_distribution_sent_set |=  SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION;

#ifdef ENABLE_LE_SIGNED_WRITE
        // hack to reproduce test runs
                    if (test_use_fixed_local_csrk){
                        memset(setup->sm_local_csrk, 0xcc, 16);
                    }

                    // store local CSRK
                    if (setup->sm_le_device_index >= 0){
                        log_info("sm: store local CSRK");
                        le_device_db_local_csrk_set(setup->sm_le_device_index, setup->sm_local_csrk);
                        le_device_db_local_counter_set(setup->sm_le_device_index, 0);
                    }
#endif

        uint8_t buffer[17];
        buffer[0] = SM_CODE_SIGNING_INFORMATION;
        reverse_128(setup->sm_local_csrk, &buffer[1]);
        sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
        sm_timeout_reset(connection);
        return;
    }
    btstack_assert(false);
}

static bool sm_ctkd_from_le(sm_connection_t *sm_connection) {
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
    // requirements to derive link key from  LE:
    // - use secure connections
    if (setup->sm_use_secure_connections == 0) return false;
    // - bonding needs to be enabled:
    bool bonding_enabled = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_BONDING ) != 0u;
    if (!bonding_enabled) return false;
    // - need identity address / public addr
    bool have_identity_address_info = ((setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION) != 0) || (setup->sm_peer_addr_type == 0);
    if (!have_identity_address_info) return false;
    // - there is no stored BR/EDR link key or the derived key has at least the same level of authentication (bail if stored key has higher authentication)
    //   this requirement is motivated by BLURtooth paper. The paper recommends to not overwrite keys at all.
    //      If SC is authenticated, we consider it safe to overwrite a stored key.
    //      If stored link key is not authenticated, it could already be compromised by a MITM attack. Allowing overwrite by unauthenticated derived key does not make it worse.
    uint8_t link_key[16];
    link_key_type_t link_key_type;
    bool have_link_key             = gap_get_link_key_for_bd_addr(setup->sm_peer_address, link_key, &link_key_type);
    bool link_key_authenticated    = gap_authenticated_for_link_key_type(link_key_type);
    bool derived_key_authenticated = sm_connection->sm_connection_authenticated != 0;
    if (have_link_key && link_key_authenticated && !derived_key_authenticated) {
        return false;
    }
    // get started (all of the above are true)
    return true;
#else
    UNUSED(sm_connection);
	return false;
#endif
}

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
static bool sm_ctkd_from_classic(sm_connection_t * sm_connection){
    hci_connection_t * hci_connection = hci_connection_for_handle(sm_connection->sm_handle);
    btstack_assert(hci_connection != NULL);
    // requirements to derive ltk from BR/EDR:
    // - BR/EDR uses secure connections
    if (gap_secure_connection_for_link_key_type(hci_connection->link_key_type) == false) return false;
    // - bonding needs to be enabled:
    bool bonding_enabled = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_BONDING ) != 0u;
    if (!bonding_enabled) return false;
    // - there is no stored LTK or the derived key has at least the same level of authentication (bail if LTK is authenticated but Link Key isn't)
    bool link_key_authenticated = gap_authenticated_for_link_key_type(hci_connection->link_key_type);
    if (link_key_authenticated) return true;
    int index = sm_le_device_db_index_lookup(BD_ADDR_TYPE_LE_PUBLIC, hci_connection->address);
    if (index >= 0){
        int ltk_authenticated;
        sm_key_t ltk;
        le_device_db_encryption_get(sm_connection->sm_le_db_index, NULL, NULL, ltk, NULL, &ltk_authenticated, NULL, NULL);
        bool have_ltk = !sm_is_null_key(ltk);
        if (have_ltk && ltk_authenticated) return false;
    }
    return true;
}
#endif

static void sm_key_distribution_complete_responder(sm_connection_t * connection){
    if (sm_ctkd_from_le(connection)){
        bool use_h7 = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_CT2) != 0;
        connection->sm_engine_state = use_h7 ? SM_SC_W2_CALCULATE_ILK_USING_H7 : SM_SC_W2_CALCULATE_ILK_USING_H6;
    } else {
        connection->sm_engine_state = SM_RESPONDER_IDLE;
        sm_pairing_complete(connection, ERROR_CODE_SUCCESS, 0);
        sm_done_for_handle(connection->sm_handle);
    }
}

static void sm_key_distribution_complete_initiator(sm_connection_t * connection){
    if (sm_ctkd_from_le(connection)){
        bool use_h7 = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_CT2) != 0;
        connection->sm_engine_state = use_h7 ? SM_SC_W2_CALCULATE_ILK_USING_H7 : SM_SC_W2_CALCULATE_ILK_USING_H6;
    } else {
        sm_master_pairing_success(connection);
    }
}

#ifdef ENABLE_LE_SECURE_CONNECTIONS
static void sm_run_state_sc_send_confirmation(sm_connection_t *connection) {
    uint8_t buffer[17];
    buffer[0] = SM_CODE_PAIRING_CONFIRM;
    reverse_128(setup->sm_local_confirm, &buffer[1]);
    if (IS_RESPONDER(connection->sm_role)){
        connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM;
    } else {
        connection->sm_engine_state = SM_SC_W4_CONFIRMATION;
    }
    sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
    sm_timeout_reset(connection);
}

static void sm_run_state_sc_send_pairing_random(sm_connection_t *connection) {
    uint8_t buffer[17];
    buffer[0] = SM_CODE_PAIRING_RANDOM;
    reverse_128(setup->sm_local_nonce, &buffer[1]);
    log_info("stk method %u, bit num: %u", setup->sm_stk_generation_method, setup->sm_passkey_bit);
    if (sm_passkey_entry(setup->sm_stk_generation_method) && (setup->sm_passkey_bit < 20u)){
        log_info("SM_SC_SEND_PAIRING_RANDOM A");
        if (IS_RESPONDER(connection->sm_role)){
            // responder
            connection->sm_engine_state = SM_SC_W4_CONFIRMATION;
        } else {
            // initiator
            connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM;
        }
    } else {
        log_info("SM_SC_SEND_PAIRING_RANDOM B");
        if (IS_RESPONDER(connection->sm_role)){
            // responder
            if (setup->sm_stk_generation_method == NUMERIC_COMPARISON){
                log_info("SM_SC_SEND_PAIRING_RANDOM B1");
                connection->sm_engine_state = SM_SC_W2_CALCULATE_G2;
            } else {
                log_info("SM_SC_SEND_PAIRING_RANDOM B2");
                sm_sc_prepare_dhkey_check(connection);
            }
        } else {
            // initiator
            connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM;
        }
    }
    sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
    sm_timeout_reset(connection);
}

static void sm_run_state_sc_send_dhkey_check_command(sm_connection_t *connection) {
    uint8_t buffer[17];
    buffer[0] = SM_CODE_PAIRING_DHKEY_CHECK;
    reverse_128(setup->sm_local_dhkey_check, &buffer[1]);

    if (IS_RESPONDER(connection->sm_role)){
        connection->sm_engine_state = SM_SC_W4_LTK_REQUEST_SC;
    } else {
        connection->sm_engine_state = SM_SC_W4_DHKEY_CHECK_COMMAND;
    }

    sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
    sm_timeout_reset(connection);
}

static void sm_run_state_sc_send_public_key_command(sm_connection_t *connection) {
    bool trigger_user_response   = false;
    bool trigger_start_calculating_local_confirm = false;
    uint8_t buffer[65];
    buffer[0] = SM_CODE_PAIRING_PUBLIC_KEY;
    //
    reverse_256(&ec_q[0],  &buffer[1]);
    reverse_256(&ec_q[32], &buffer[33]);

#ifdef ENABLE_TESTING_SUPPORT
    if (test_pairing_failure == SM_REASON_DHKEY_CHECK_FAILED){
            log_info("testing_support: invalidating public key");
            // flip single bit of public key coordinate
            buffer[1] ^= 1;
        }
#endif

    // stk generation method
// passkey entry: notify app to show passkey or to request passkey
    switch (setup->sm_stk_generation_method){
        case JUST_WORKS:
        case NUMERIC_COMPARISON:
            if (IS_RESPONDER(connection->sm_role)){
                // responder
                trigger_start_calculating_local_confirm = true;
                connection->sm_engine_state = SM_SC_W4_LOCAL_NONCE;
            } else {
                // initiator
                connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND;
            }
            break;
        case PK_INIT_INPUT:
        case PK_RESP_INPUT:
        case PK_BOTH_INPUT:
            // use random TK for display
            (void)memcpy(setup->sm_ra, setup->sm_tk, 16);
            (void)memcpy(setup->sm_rb, setup->sm_tk, 16);
            setup->sm_passkey_bit = 0;

            if (IS_RESPONDER(connection->sm_role)){
                // responder
                connection->sm_engine_state = SM_SC_W4_CONFIRMATION;
            } else {
                // initiator
                connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND;
            }
            trigger_user_response = true;
            break;
        case OOB:
            if (IS_RESPONDER(connection->sm_role)){
                // responder
                connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM;
            } else {
                // initiator
                connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND;
            }
            break;
        default:
            btstack_assert(false);
            break;
    }

    sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
    sm_timeout_reset(connection);

    // trigger user response and calc confirm after sending pdu
    if (trigger_user_response){
        sm_trigger_user_response(connection);
    }
    if (trigger_start_calculating_local_confirm){
        sm_sc_start_calculating_local_confirm(connection);
    }
}
#endif

static bool sm_run_non_connection_logic(void){
    bool done;;

    done = sm_run_dpkg();
    if (done) return true;

    done = sm_run_rau();
    if (done) return true;

    done = sm_run_csrk();
    if (done) return true;

    done = sm_run_oob();
    return done;
}

static void sm_run(void){

    // assert that stack has already bootet
    if (hci_get_state() != HCI_STATE_WORKING) return;

    // assert that we can send at least commands
    if (!hci_can_send_command_packet_now()) return;

    // pause until IR/ER are ready
    if (sm_persistent_keys_random_active) return;

    // non-connection related behaviour
    bool done = sm_run_non_connection_logic();
    if (done) return;

    // assert that we can send at least commands - cmd might have been sent by crypto engine
    if (!hci_can_send_command_packet_now()) return;

    // handle basic actions that don't requires the full context
    done = sm_run_basic();
    if (done) return;

    //
    // active connection handling
    // -- use loop to handle next connection if lock on setup context is released

    while (true) {

        sm_run_activate_connection();

        if (sm_active_connection_handle == HCI_CON_HANDLE_INVALID) return;

        //
        // active connection handling
        //

        sm_connection_t * connection = sm_get_connection_for_handle(sm_active_connection_handle);
        if (!connection) {
            log_info("no connection for handle 0x%04x", sm_active_connection_handle);
            return;
        }

        // assert that we could send a SM PDU - not needed for all of the following
        if (!l2cap_can_send_fixed_channel_packet_now(sm_active_connection_handle, connection->sm_cid)) {
            log_info("cannot send now, requesting can send now event");
            l2cap_request_can_send_fix_channel_now_event(sm_active_connection_handle, connection->sm_cid);
            return;
        }

        // send keypress notifications
        if (setup->sm_keypress_notification){
            sm_run_send_keypress_notification(connection);
            return;
        }

#ifdef ENABLE_LE_SECURE_CONNECTIONS
        // assert that sm cmac engine is ready
        if (sm_cmac_ready() == false){
            break;
        }
#endif

        int key_distribution_flags;
        UNUSED(key_distribution_flags);
#ifdef ENABLE_LE_PERIPHERAL
        int err;
        bool have_ltk;
        uint8_t ltk[16];
#endif

        log_info("sm_run: state %u", connection->sm_engine_state);
        switch (connection->sm_engine_state){

            // secure connections, initiator + responding states
#ifdef ENABLE_LE_SECURE_CONNECTIONS
            case SM_SC_W2_CMAC_FOR_CONFIRMATION:
                connection->sm_engine_state = SM_SC_W4_CMAC_FOR_CONFIRMATION;
                sm_sc_calculate_local_confirm(connection);
                break;
            case SM_SC_W2_CMAC_FOR_CHECK_CONFIRMATION:
                connection->sm_engine_state = SM_SC_W4_CMAC_FOR_CHECK_CONFIRMATION;
                sm_sc_calculate_remote_confirm(connection);
                break;
            case SM_SC_W2_CALCULATE_F6_FOR_DHKEY_CHECK:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_F6_FOR_DHKEY_CHECK;
                sm_sc_calculate_f6_for_dhkey_check(connection);
                break;
            case SM_SC_W2_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK;
                sm_sc_calculate_f6_to_verify_dhkey_check(connection);
                break;
            case SM_SC_W2_CALCULATE_F5_SALT:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_F5_SALT;
                f5_calculate_salt(connection);
                break;
            case SM_SC_W2_CALCULATE_F5_MACKEY:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_F5_MACKEY;
                f5_calculate_mackey(connection);
                break;
            case SM_SC_W2_CALCULATE_F5_LTK:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_F5_LTK;
                f5_calculate_ltk(connection);
                break;
            case SM_SC_W2_CALCULATE_G2:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_G2;
                g2_calculate(connection);
                break;
#endif

#ifdef ENABLE_LE_CENTRAL
            // initiator side

            case SM_INITIATOR_PH4_HAS_LTK: {
				sm_reset_setup();
				sm_load_security_info(connection);

                sm_key_t peer_ltk_flipped;
                reverse_128(setup->sm_peer_ltk, peer_ltk_flipped);
                connection->sm_engine_state = SM_PH4_W4_CONNECTION_ENCRYPTED;
                log_info("sm: hci_le_start_encryption ediv 0x%04x", setup->sm_peer_ediv);
                uint32_t rand_high = big_endian_read_32(setup->sm_peer_rand, 0);
                uint32_t rand_low  = big_endian_read_32(setup->sm_peer_rand, 4);
                hci_send_cmd(&hci_le_start_encryption, connection->sm_handle,rand_low, rand_high, setup->sm_peer_ediv, peer_ltk_flipped);

                // notify after sending
                sm_reencryption_started(connection);
                return;
            }

			case SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST:
				sm_reset_setup();
				sm_init_setup(connection);

                sm_pairing_packet_set_code(setup->sm_m_preq, SM_CODE_PAIRING_REQUEST);
                connection->sm_engine_state = SM_INITIATOR_PH1_W4_PAIRING_RESPONSE;
                sm_send_connectionless(connection, (uint8_t*) &setup->sm_m_preq, sizeof(sm_pairing_packet_t));
                sm_timeout_reset(connection);

                // notify after sending
                sm_pairing_started(connection);
                break;
#endif

#ifdef ENABLE_LE_SECURE_CONNECTIONS
            case SM_SC_SEND_PUBLIC_KEY_COMMAND:
                sm_run_state_sc_send_public_key_command(connection);
                break;
            case SM_SC_SEND_CONFIRMATION:
                sm_run_state_sc_send_confirmation(connection);
                break;
            case SM_SC_SEND_PAIRING_RANDOM:
                sm_run_state_sc_send_pairing_random(connection);
                break;
            case SM_SC_SEND_DHKEY_CHECK_COMMAND:
                sm_run_state_sc_send_dhkey_check_command(connection);
                break;
#endif

#ifdef ENABLE_LE_PERIPHERAL

			case SM_RESPONDER_SEND_SECURITY_REQUEST: {
				const uint8_t buffer[2] = {SM_CODE_SECURITY_REQUEST, sm_auth_req};
				connection->sm_engine_state = SM_RESPONDER_PH1_W4_PAIRING_REQUEST;
				sm_send_connectionless(connection,  (uint8_t *) buffer, sizeof(buffer));
				sm_timeout_start(connection);
				break;
			}

#ifdef ENABLE_LE_SECURE_CONNECTIONS
			case SM_SC_RECEIVED_LTK_REQUEST:
				switch (connection->sm_irk_lookup_state){
					case IRK_LOOKUP_SUCCEEDED:
						// assuming Secure Connection, we have a stored LTK and the EDIV/RAND are null
						// start using context by loading security info
						sm_reset_setup();
						sm_load_security_info(connection);
						if ((setup->sm_peer_ediv == 0u) && sm_is_null_random(setup->sm_peer_rand) && !sm_is_null_key(setup->sm_peer_ltk)){
							(void)memcpy(setup->sm_ltk, setup->sm_peer_ltk, 16);
							connection->sm_engine_state = SM_RESPONDER_PH4_SEND_LTK_REPLY;
                            sm_reencryption_started(connection);
                            sm_trigger_run();
							break;
						}
						log_info("LTK Request: ediv & random are empty, but no stored LTK (IRK Lookup Succeeded)");
						connection->sm_engine_state = SM_RESPONDER_IDLE;
						hci_send_cmd(&hci_le_long_term_key_negative_reply, connection->sm_handle);
						return;
					default:
						// just wait until IRK lookup is completed
						break;
				}
				break;
#endif /* ENABLE_LE_SECURE_CONNECTIONS */

			case SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED:
                sm_reset_setup();

			    // handle Pairing Request with LTK available
                switch (connection->sm_irk_lookup_state) {
                    case IRK_LOOKUP_SUCCEEDED:
                        le_device_db_encryption_get(connection->sm_le_db_index, NULL, NULL, ltk, NULL, NULL, NULL, NULL);
                        have_ltk = !sm_is_null_key(ltk);
                        if (have_ltk){
                            log_info("pairing request but LTK available");
                            // emit re-encryption start/fail sequence
                            sm_reencryption_started(connection);
                            sm_reencryption_complete(connection, ERROR_CODE_PIN_OR_KEY_MISSING);
                        }
                        break;
                    default:
                        break;
                }

				sm_init_setup(connection);

				// recover pairing request
				(void)memcpy(&setup->sm_m_preq, &connection->sm_m_preq, sizeof(sm_pairing_packet_t));
				err = sm_stk_generation_init(connection);

#ifdef ENABLE_TESTING_SUPPORT
				if ((0 < test_pairing_failure) && (test_pairing_failure < SM_REASON_DHKEY_CHECK_FAILED)){
                        log_info("testing_support: respond with pairing failure %u", test_pairing_failure);
                        err = test_pairing_failure;
                    }
#endif
				if (err != 0){
                    // emit pairing started/failed sequence
                    sm_pairing_started(connection);
                    sm_pairing_error(connection, err);
					sm_trigger_run();
					break;
				}

				sm_timeout_start(connection);

				// generate random number first, if we need to show passkey, otherwise send response
				if (setup->sm_stk_generation_method == PK_INIT_INPUT){
					btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph2_tk, (void *)(uintptr_t) connection->sm_handle);
					break;
				}

				/* fall through */

            case SM_RESPONDER_PH1_SEND_PAIRING_RESPONSE:
                sm_pairing_packet_set_code(setup->sm_s_pres,SM_CODE_PAIRING_RESPONSE);

                // start with initiator key dist flags
                key_distribution_flags = sm_key_distribution_flags_for_auth_req();

#ifdef ENABLE_LE_SECURE_CONNECTIONS
                // LTK (= encyrption information & master identification) only exchanged for LE Legacy Connection
                if (setup->sm_use_secure_connections){
                    key_distribution_flags &= ~SM_KEYDIST_ENC_KEY;
                }
#endif
                // setup in response
                sm_pairing_packet_set_initiator_key_distribution(setup->sm_s_pres, sm_pairing_packet_get_initiator_key_distribution(setup->sm_m_preq) & key_distribution_flags);
                sm_pairing_packet_set_responder_key_distribution(setup->sm_s_pres, sm_pairing_packet_get_responder_key_distribution(setup->sm_m_preq) & key_distribution_flags);

                // update key distribution after ENC was dropped
                sm_setup_key_distribution(sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres), sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres));

                if (setup->sm_use_secure_connections){
                    connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND;
                } else {
                    connection->sm_engine_state = SM_RESPONDER_PH1_W4_PAIRING_CONFIRM;
                }

                sm_send_connectionless(connection, (uint8_t*) &setup->sm_s_pres, sizeof(sm_pairing_packet_t));
                sm_timeout_reset(connection);

                // notify after sending
                sm_pairing_started(connection);

                // SC Numeric Comparison will trigger user response after public keys & nonces have been exchanged
                if (!setup->sm_use_secure_connections || (setup->sm_stk_generation_method == JUST_WORKS)){
                    sm_trigger_user_response(connection);
                }
                return;
#endif

            case SM_PH2_SEND_PAIRING_RANDOM: {
                uint8_t buffer[17];
                buffer[0] = SM_CODE_PAIRING_RANDOM;
                reverse_128(setup->sm_local_random, &buffer[1]);
                if (IS_RESPONDER(connection->sm_role)){
                    connection->sm_engine_state = SM_RESPONDER_PH2_W4_LTK_REQUEST;
                } else {
                    connection->sm_engine_state = SM_INITIATOR_PH2_W4_PAIRING_RANDOM;
                }
                sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
                sm_timeout_reset(connection);
                break;
            }

            case SM_PH2_C1_GET_ENC_A:
                // already busy?
                if (sm_aes128_state == SM_AES128_ACTIVE) break;
                // calculate confirm using aes128 engine - step 1
                sm_c1_t1(setup->sm_local_random, (uint8_t*) &setup->sm_m_preq, (uint8_t*) &setup->sm_s_pres, setup->sm_m_addr_type, setup->sm_s_addr_type, sm_aes128_plaintext);
                connection->sm_engine_state = SM_PH2_C1_W4_ENC_A;
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_a, (void *)(uintptr_t) connection->sm_handle);
                break;

            case SM_PH2_C1_GET_ENC_C:
                // already busy?
                if (sm_aes128_state == SM_AES128_ACTIVE) break;
                // calculate m_confirm using aes128 engine - step 1
                sm_c1_t1(setup->sm_peer_random, (uint8_t*) &setup->sm_m_preq, (uint8_t*) &setup->sm_s_pres, setup->sm_m_addr_type, setup->sm_s_addr_type, sm_aes128_plaintext);
                connection->sm_engine_state = SM_PH2_C1_W4_ENC_C;
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_c, (void *)(uintptr_t) connection->sm_handle);
                break;

            case SM_PH2_CALC_STK:
                // already busy?
                if (sm_aes128_state == SM_AES128_ACTIVE) break;
                // calculate STK
                if (IS_RESPONDER(connection->sm_role)){
                    sm_s1_r_prime(setup->sm_local_random, setup->sm_peer_random, sm_aes128_plaintext);
                } else {
                    sm_s1_r_prime(setup->sm_peer_random, setup->sm_local_random, sm_aes128_plaintext);
                }
                connection->sm_engine_state = SM_PH2_W4_STK;
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_stk, (void *)(uintptr_t) connection->sm_handle);
                break;

            case SM_PH3_Y_GET_ENC:
                // already busy?
                if (sm_aes128_state == SM_AES128_ACTIVE) break;
                // PH3B2 - calculate Y from      - enc

                // dm helper (was sm_dm_r_prime)
                // r' = padding || r
                // r - 64 bit value
                memset(&sm_aes128_plaintext[0], 0, 8);
                (void)memcpy(&sm_aes128_plaintext[8], setup->sm_local_rand, 8);

                // Y = dm(DHK, Rand)
                connection->sm_engine_state = SM_PH3_Y_W4_ENC;
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_dhk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_ph3_y, (void *)(uintptr_t) connection->sm_handle);
                break;

            case SM_PH2_C1_SEND_PAIRING_CONFIRM: {
                uint8_t buffer[17];
                buffer[0] = SM_CODE_PAIRING_CONFIRM;
                reverse_128(setup->sm_local_confirm, &buffer[1]);
                if (IS_RESPONDER(connection->sm_role)){
                    connection->sm_engine_state = SM_RESPONDER_PH2_W4_PAIRING_RANDOM;
                } else {
                    connection->sm_engine_state = SM_INITIATOR_PH2_W4_PAIRING_CONFIRM;
                }
                sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer));
                sm_timeout_reset(connection);
                return;
            }
#ifdef ENABLE_LE_PERIPHERAL
            case SM_RESPONDER_PH2_SEND_LTK_REPLY: {
                // cache key before using
                sm_cache_ltk(connection, setup->sm_ltk);
                sm_key_t stk_flipped;
                reverse_128(setup->sm_ltk, stk_flipped);
                connection->sm_engine_state = SM_PH2_W4_CONNECTION_ENCRYPTED;
                hci_send_cmd(&hci_le_long_term_key_request_reply, connection->sm_handle, stk_flipped);
                return;
            }
            case SM_RESPONDER_PH4_SEND_LTK_REPLY: {
                // allow to override LTK
                if (sm_get_ltk_callback != NULL){
                    (void)(*sm_get_ltk_callback)(connection->sm_handle, connection->sm_peer_addr_type, connection->sm_peer_address, setup->sm_ltk);
                }
                // cache key before using
                sm_cache_ltk(connection, setup->sm_ltk);
                sm_key_t ltk_flipped;
                reverse_128(setup->sm_ltk, ltk_flipped);
                connection->sm_engine_state = SM_PH4_W4_CONNECTION_ENCRYPTED;
                hci_send_cmd(&hci_le_long_term_key_request_reply, connection->sm_handle, ltk_flipped);
                return;
            }

			case SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST:
                // already busy?
                if (sm_aes128_state == SM_AES128_ACTIVE) break;
                log_info("LTK Request: recalculating with ediv 0x%04x", setup->sm_local_ediv);

				sm_reset_setup();
				sm_start_calculating_ltk_from_ediv_and_rand(connection);

				sm_reencryption_started(connection);

                // dm helper (was sm_dm_r_prime)
                // r' = padding || r
                // r - 64 bit value
                memset(&sm_aes128_plaintext[0], 0, 8);
                (void)memcpy(&sm_aes128_plaintext[8], setup->sm_local_rand, 8);

                // Y = dm(DHK, Rand)
                connection->sm_engine_state = SM_RESPONDER_PH4_Y_W4_ENC;
                sm_aes128_state = SM_AES128_ACTIVE;
                btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_dhk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_ph4_y, (void *)(uintptr_t) connection->sm_handle);
                return;
#endif
#ifdef ENABLE_LE_CENTRAL
            case SM_INITIATOR_PH3_SEND_START_ENCRYPTION: {
                sm_key_t stk_flipped;
                reverse_128(setup->sm_ltk, stk_flipped);
                connection->sm_engine_state = SM_PH2_W4_CONNECTION_ENCRYPTED;
                hci_send_cmd(&hci_le_start_encryption, connection->sm_handle, 0, 0, 0, stk_flipped);
                return;
            }
#endif

            case SM_PH3_DISTRIBUTE_KEYS:
                // send next key
                if (setup->sm_key_distribution_send_set != 0){
                    sm_run_distribute_keys(connection);
                }

                // more to send?
                if (setup->sm_key_distribution_send_set != 0){
                    return;
                }

                // keys are sent
                if (IS_RESPONDER(connection->sm_role)){
                    // slave -> receive master keys if any
                    if (sm_key_distribution_all_received()){
                        sm_key_distribution_handle_all_received(connection);
                        sm_key_distribution_complete_responder(connection);
                        // start CTKD right away
                        continue;
                    } else {
                        connection->sm_engine_state = SM_PH3_RECEIVE_KEYS;
                    }
                } else {
                    sm_master_pairing_success(connection);
                }
                break;

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
            case SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST:
                // fill in sm setup (lite version of sm_init_setup)
                sm_reset_setup();
                setup->sm_peer_addr_type = connection->sm_peer_addr_type;
                setup->sm_m_addr_type = connection->sm_peer_addr_type;
                setup->sm_s_addr_type = connection->sm_own_addr_type;
                (void) memcpy(setup->sm_peer_address, connection->sm_peer_address, 6);
                (void) memcpy(setup->sm_m_address, connection->sm_peer_address, 6);
                (void) memcpy(setup->sm_s_address, connection->sm_own_address, 6);
                setup->sm_use_secure_connections = true;
                sm_ctkd_fetch_br_edr_link_key(connection);

                // Enc Key and IRK if requested
                key_distribution_flags = SM_KEYDIST_ID_KEY | SM_KEYDIST_ENC_KEY;
#ifdef ENABLE_LE_SIGNED_WRITE
                // Plus signing key if supported
                key_distribution_flags |= SM_KEYDIST_ID_KEY;
#endif
                sm_pairing_packet_set_code(setup->sm_m_preq, SM_CODE_PAIRING_REQUEST);
                sm_pairing_packet_set_io_capability(setup->sm_m_preq, 0);
                sm_pairing_packet_set_oob_data_flag(setup->sm_m_preq, 0);
                sm_pairing_packet_set_auth_req(setup->sm_m_preq, SM_AUTHREQ_CT2);
                sm_pairing_packet_set_max_encryption_key_size(setup->sm_m_preq, sm_max_encryption_key_size);
                sm_pairing_packet_set_initiator_key_distribution(setup->sm_m_preq, key_distribution_flags);
                sm_pairing_packet_set_responder_key_distribution(setup->sm_m_preq, key_distribution_flags);

                // set state and send pairing response
                sm_timeout_start(connection);
                connection->sm_engine_state = SM_BR_EDR_INITIATOR_W4_PAIRING_RESPONSE;
                sm_send_connectionless(connection, (uint8_t *) &setup->sm_m_preq, sizeof(sm_pairing_packet_t));
                break;

            case SM_BR_EDR_RESPONDER_PAIRING_REQUEST_RECEIVED:
                // fill in sm setup (lite version of sm_init_setup)
                sm_reset_setup();
                setup->sm_peer_addr_type = connection->sm_peer_addr_type;
                setup->sm_m_addr_type = connection->sm_peer_addr_type;
                setup->sm_s_addr_type = connection->sm_own_addr_type;
                (void) memcpy(setup->sm_peer_address, connection->sm_peer_address, 6);
                (void) memcpy(setup->sm_m_address, connection->sm_peer_address, 6);
                (void) memcpy(setup->sm_s_address, connection->sm_own_address, 6);
                setup->sm_use_secure_connections = true;
                sm_ctkd_fetch_br_edr_link_key(connection);
                (void) memcpy(&setup->sm_m_preq, &connection->sm_m_preq, sizeof(sm_pairing_packet_t));

                // Enc Key and IRK if requested
                key_distribution_flags = SM_KEYDIST_ID_KEY | SM_KEYDIST_ENC_KEY;
#ifdef ENABLE_LE_SIGNED_WRITE
                // Plus signing key if supported
                key_distribution_flags |= SM_KEYDIST_ID_KEY;
#endif
                // drop flags not requested by initiator
                key_distribution_flags &= sm_pairing_packet_get_initiator_key_distribution(connection->sm_m_preq);

                // If Secure Connections pairing has been initiated over BR/EDR, the following fields of the SM Pairing Request PDU are reserved for future use:
                // - the IO Capability field,
                // - the OOB data flag field, and
                // - all bits in the Auth Req field except the CT2 bit.
                sm_pairing_packet_set_code(setup->sm_s_pres, SM_CODE_PAIRING_RESPONSE);
                sm_pairing_packet_set_io_capability(setup->sm_s_pres, 0);
                sm_pairing_packet_set_oob_data_flag(setup->sm_s_pres, 0);
                sm_pairing_packet_set_auth_req(setup->sm_s_pres, SM_AUTHREQ_CT2);
                sm_pairing_packet_set_max_encryption_key_size(setup->sm_s_pres, connection->sm_actual_encryption_key_size);
                sm_pairing_packet_set_initiator_key_distribution(setup->sm_s_pres, key_distribution_flags);
                sm_pairing_packet_set_responder_key_distribution(setup->sm_s_pres, key_distribution_flags);

                // configure key distribution, LTK is derived locally
                key_distribution_flags &= ~SM_KEYDIST_ENC_KEY;
                sm_setup_key_distribution(key_distribution_flags, key_distribution_flags);

                // set state and send pairing response
                sm_timeout_start(connection);
                connection->sm_engine_state = SM_BR_EDR_DISTRIBUTE_KEYS;
                sm_send_connectionless(connection, (uint8_t *) &setup->sm_s_pres, sizeof(sm_pairing_packet_t));
                break;
            case SM_BR_EDR_DISTRIBUTE_KEYS:
                if (setup->sm_key_distribution_send_set != 0) {
                    sm_run_distribute_keys(connection);
                    return;
                }
                // keys are sent
                if (IS_RESPONDER(connection->sm_role)) {
                    // responder -> receive master keys if there are any
                    if (!sm_key_distribution_all_received()){
                        connection->sm_engine_state = SM_BR_EDR_RECEIVE_KEYS;
                        break;
                    }
                }
                // otherwise start CTKD right away (responder and no keys to receive / initiator)
                sm_ctkd_start_from_br_edr(connection);
                continue;
            case SM_SC_W2_CALCULATE_ILK_USING_H6:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_ILK;
                h6_calculate_ilk_from_le_ltk(connection);
                break;
            case SM_SC_W2_CALCULATE_BR_EDR_LINK_KEY:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_BR_EDR_LINK_KEY;
                h6_calculate_br_edr_link_key(connection);
                break;
            case SM_SC_W2_CALCULATE_ILK_USING_H7:
                connection->sm_engine_state = SM_SC_W4_CALCULATE_ILK;
                h7_calculate_ilk_from_le_ltk(connection);
                break;
            case SM_BR_EDR_W2_CALCULATE_ILK_USING_H6:
                connection->sm_engine_state = SM_BR_EDR_W4_CALCULATE_ILK;
                h6_calculate_ilk_from_br_edr(connection);
                break;
            case SM_BR_EDR_W2_CALCULATE_LE_LTK:
                connection->sm_engine_state = SM_BR_EDR_W4_CALCULATE_LE_LTK;
                h6_calculate_le_ltk(connection);
                break;
            case SM_BR_EDR_W2_CALCULATE_ILK_USING_H7:
                connection->sm_engine_state = SM_BR_EDR_W4_CALCULATE_ILK;
                h7_calculate_ilk_from_br_edr(connection);
                break;
#endif

            default:
                break;
        }

        // check again if active connection was released
        if (sm_active_connection_handle != HCI_CON_HANDLE_INVALID) break;
    }
}

// sm_aes128_state stays active
static void sm_handle_encryption_result_enc_a(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    sm_c1_t3(sm_aes128_ciphertext, setup->sm_m_address, setup->sm_s_address, setup->sm_c1_t3_value);
    sm_aes128_state = SM_AES128_ACTIVE;
    btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, setup->sm_c1_t3_value, setup->sm_local_confirm, sm_handle_encryption_result_enc_b, (void *)(uintptr_t) connection->sm_handle);
}

static void sm_handle_encryption_result_enc_b(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    log_info_key("c1!", setup->sm_local_confirm);
    connection->sm_engine_state = SM_PH2_C1_SEND_PAIRING_CONFIRM;
    sm_trigger_run();
}

// sm_aes128_state stays active
static void sm_handle_encryption_result_enc_c(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    sm_c1_t3(sm_aes128_ciphertext, setup->sm_m_address, setup->sm_s_address, setup->sm_c1_t3_value);
    sm_aes128_state = SM_AES128_ACTIVE;
    btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, setup->sm_c1_t3_value, sm_aes128_ciphertext, sm_handle_encryption_result_enc_d, (void *)(uintptr_t) connection->sm_handle);
}

static void sm_handle_encryption_result_enc_d(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    log_info_key("c1!", sm_aes128_ciphertext);
    if (memcmp(setup->sm_peer_confirm, sm_aes128_ciphertext, 16) != 0){
        sm_pairing_error(connection, SM_REASON_CONFIRM_VALUE_FAILED);
        sm_trigger_run();
        return;
    }
    if (IS_RESPONDER(connection->sm_role)){
        connection->sm_engine_state = SM_PH2_SEND_PAIRING_RANDOM;
        sm_trigger_run();
    } else {
        sm_s1_r_prime(setup->sm_peer_random, setup->sm_local_random, sm_aes128_plaintext);
        sm_aes128_state = SM_AES128_ACTIVE;
        btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_stk, (void *)(uintptr_t) connection->sm_handle);
    }
}

static void sm_handle_encryption_result_enc_stk(void *arg){
    sm_aes128_state = SM_AES128_IDLE;
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    sm_truncate_key(setup->sm_ltk, connection->sm_actual_encryption_key_size);
    log_info_key("stk", setup->sm_ltk);
    if (IS_RESPONDER(connection->sm_role)){
        connection->sm_engine_state = SM_RESPONDER_PH2_SEND_LTK_REPLY;
    } else {
        connection->sm_engine_state = SM_INITIATOR_PH3_SEND_START_ENCRYPTION;
    }
    sm_trigger_run();
}

// sm_aes128_state stays active
static void sm_handle_encryption_result_enc_ph3_y(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    setup->sm_local_y = big_endian_read_16(sm_aes128_ciphertext, 14);
    log_info_hex16("y", setup->sm_local_y);
    // PH3B3 - calculate EDIV
    setup->sm_local_ediv = setup->sm_local_y ^ setup->sm_local_div;
    log_info_hex16("ediv", setup->sm_local_ediv);
    // PH3B4 - calculate LTK         - enc
    // LTK = d1(ER, DIV, 0))
    sm_d1_d_prime(setup->sm_local_div, 0, sm_aes128_plaintext);
    sm_aes128_state = SM_AES128_ACTIVE;
    btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_er, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_ph3_ltk, (void *)(uintptr_t) connection->sm_handle);
}

#ifdef ENABLE_LE_PERIPHERAL
// sm_aes128_state stays active
static void sm_handle_encryption_result_enc_ph4_y(void *arg){
    sm_aes128_state = SM_AES128_IDLE;
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    setup->sm_local_y = big_endian_read_16(sm_aes128_ciphertext, 14);
    log_info_hex16("y", setup->sm_local_y);

    // PH3B3 - calculate DIV
    setup->sm_local_div = setup->sm_local_y ^ setup->sm_local_ediv;
    log_info_hex16("ediv", setup->sm_local_ediv);
    // PH3B4 - calculate LTK         - enc
    // LTK = d1(ER, DIV, 0))
    sm_d1_d_prime(setup->sm_local_div, 0, sm_aes128_plaintext);
    sm_aes128_state = SM_AES128_ACTIVE;
    btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_er, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_ph4_ltk, (void *)(uintptr_t) connection->sm_handle);
}
#endif

// sm_aes128_state stays active
static void sm_handle_encryption_result_enc_ph3_ltk(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    log_info_key("ltk", setup->sm_ltk);
    // calc CSRK next
    sm_d1_d_prime(setup->sm_local_div, 1, sm_aes128_plaintext);
    sm_aes128_state = SM_AES128_ACTIVE;
    btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_er, sm_aes128_plaintext, setup->sm_local_csrk, sm_handle_encryption_result_enc_csrk, (void *)(uintptr_t) connection->sm_handle);
}

static void sm_handle_encryption_result_enc_csrk(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    sm_aes128_state = SM_AES128_IDLE;
    log_info_key("csrk", setup->sm_local_csrk);
    if (setup->sm_key_distribution_send_set){
        connection->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS;
    } else {
        // no keys to send, just continue
        if (IS_RESPONDER(connection->sm_role)){
            if (sm_key_distribution_all_received()){
                sm_key_distribution_handle_all_received(connection);
                sm_key_distribution_complete_responder(connection);
            } else {
                // slave -> receive master keys
                connection->sm_engine_state = SM_PH3_RECEIVE_KEYS;
            }
        } else {
            sm_key_distribution_complete_initiator(connection);
        }
    }
    sm_trigger_run();
}

#ifdef ENABLE_LE_PERIPHERAL
static void sm_handle_encryption_result_enc_ph4_ltk(void *arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_aes128_state = SM_AES128_IDLE;

    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    sm_truncate_key(setup->sm_ltk, connection->sm_actual_encryption_key_size);
    log_info_key("ltk", setup->sm_ltk);
    connection->sm_engine_state = SM_RESPONDER_PH4_SEND_LTK_REPLY;
    sm_trigger_run();
}
#endif

static void sm_handle_encryption_result_address_resolution(void *arg){
    UNUSED(arg);
    sm_aes128_state = SM_AES128_IDLE;

    // compare calulated address against connecting device
    uint8_t * hash = &sm_aes128_ciphertext[13];
    if (memcmp(&sm_address_resolution_address[3], hash, 3) == 0){
        log_info("LE Device Lookup: matched resolvable private address");
        sm_address_resolution_handle_event(ADDRESS_RESOLUTION_SUCCEEDED);
        sm_trigger_run();
        return;
    }
    // no match, try next
    sm_address_resolution_test++;
    sm_trigger_run();
}

static void sm_handle_encryption_result_dkg_irk(void *arg){
    UNUSED(arg);
    sm_aes128_state = SM_AES128_IDLE;

    log_info_key("irk", sm_persistent_irk);
    dkg_state = DKG_CALC_DHK;
    sm_trigger_run();
}

static void sm_handle_encryption_result_dkg_dhk(void *arg){
    UNUSED(arg);
    sm_aes128_state = SM_AES128_IDLE;

    log_info_key("dhk", sm_persistent_dhk);
    dkg_state = DKG_READY;
    sm_trigger_run();
}

static void sm_handle_encryption_result_rau(void *arg){
    UNUSED(arg);
    sm_aes128_state = SM_AES128_IDLE;

    (void)memcpy(&sm_random_address[3], &sm_aes128_ciphertext[13], 3);
    rau_state = RAU_IDLE;
    hci_le_random_address_set(sm_random_address);

    sm_trigger_run();
}

static void sm_handle_random_result_rau(void * arg){
    UNUSED(arg);
    // non-resolvable vs. resolvable
    switch (gap_random_adress_type){
        case GAP_RANDOM_ADDRESS_RESOLVABLE:
            // resolvable: use random as prand and calc address hash
            // "The two most significant bits of prand shall be equal to ‘0’ and ‘1"
            sm_random_address[0u] &= 0x3fu;
            sm_random_address[0u] |= 0x40u;
            rau_state = RAU_GET_ENC;
            break;
        case GAP_RANDOM_ADDRESS_NON_RESOLVABLE:
        default:
            // "The two most significant bits of the address shall be equal to ‘0’""
            sm_random_address[0u] &= 0x3fu;
            rau_state = RAU_IDLE;
            hci_le_random_address_set(sm_random_address);
            break;
    }
    sm_trigger_run();
}

#ifdef ENABLE_LE_SECURE_CONNECTIONS
static void sm_handle_random_result_sc_next_send_pairing_random(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    connection->sm_engine_state = SM_SC_SEND_PAIRING_RANDOM;
    sm_trigger_run();
}

static void sm_handle_random_result_sc_next_w2_cmac_for_confirmation(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    connection->sm_engine_state = SM_SC_W2_CMAC_FOR_CONFIRMATION;
    sm_trigger_run();
}
#endif

static void sm_handle_random_result_ph2_random(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    connection->sm_engine_state = SM_PH2_C1_GET_ENC_A;
    sm_trigger_run();
}

static void sm_handle_random_result_ph2_tk(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    sm_reset_tk();
    uint32_t tk;
    if (sm_fixed_passkey_in_display_role == 0xffffffffU){
        // map random to 0-999999 without speding much cycles on a modulus operation
        tk = little_endian_read_32(sm_random_data,0);
        tk = tk & 0xfffff;  // 1048575
        if (tk >= 999999u){
            tk = tk - 999999u;
        }
    } else {
        // override with pre-defined passkey
        tk = sm_fixed_passkey_in_display_role;
    }
    big_endian_store_32(setup->sm_tk, 12, tk);
    if (IS_RESPONDER(connection->sm_role)){
        connection->sm_engine_state = SM_RESPONDER_PH1_SEND_PAIRING_RESPONSE;
    } else {
        if (setup->sm_use_secure_connections){
            connection->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND;
        } else {
            connection->sm_engine_state = SM_PH1_W4_USER_RESPONSE;
            sm_trigger_user_response(connection);
            // response_idle == nothing <--> sm_trigger_user_response() did not require response
            if (setup->sm_user_response == SM_USER_RESPONSE_IDLE){
                btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) connection->sm_handle);
            }
        }
    }
    sm_trigger_run();
}

static void sm_handle_random_result_ph3_div(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    // use 16 bit from random value as div
    setup->sm_local_div = big_endian_read_16(sm_random_data, 0);
    log_info_hex16("div", setup->sm_local_div);
    connection->sm_engine_state = SM_PH3_Y_GET_ENC;
    sm_trigger_run();
}

static void sm_handle_random_result_ph3_random(void * arg){
    hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg;
    sm_connection_t * connection = sm_get_connection_for_handle(con_handle);
    if (connection == NULL) return;

    reverse_64(sm_random_data, setup->sm_local_rand);
    // no db for encryption size hack: encryption size is stored in lowest nibble of setup->sm_local_rand
    setup->sm_local_rand[7u] = (setup->sm_local_rand[7u] & 0xf0u) + (connection->sm_actual_encryption_key_size - 1u);
    // no db for authenticated flag hack: store flag in bit 4 of LSB
    setup->sm_local_rand[7u] = (setup->sm_local_rand[7u] & 0xefu) + (connection->sm_connection_authenticated << 4u);
    btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 2, &sm_handle_random_result_ph3_div, (void *)(uintptr_t) connection->sm_handle);
}
static void sm_validate_er_ir(void){
    // warn about default ER/IR
    bool warning = false;
    if (sm_ir_is_default()){
        warning = true;
        log_error("Persistent IR not set with sm_set_ir. Use of private addresses will cause pairing issues");
    }
    if (sm_er_is_default()){
        warning = true;
        log_error("Persistent ER not set with sm_set_er. Legacy Pairing LTK is not secure");
    }
    if (warning) {
        log_error("Please configure btstack_tlv to let BTstack setup ER and IR keys");
    }
}

static void sm_handle_random_result_ir(void *arg){
    sm_persistent_keys_random_active = false;
    if (arg != NULL){
        // key generated, store in tlv
        int status = sm_tlv_impl->store_tag(sm_tlv_context, BTSTACK_TAG32('S','M','I','R'), sm_persistent_ir, 16u);
        log_info("Generated IR key. Store in TLV status: %d", status);
        UNUSED(status);
    }
    log_info_key("IR", sm_persistent_ir);
    dkg_state = DKG_CALC_IRK;

    if (test_use_fixed_local_irk){
        log_info_key("IRK", sm_persistent_irk);
        dkg_state = DKG_CALC_DHK;
    }

    sm_trigger_run();
}

static void sm_handle_random_result_er(void *arg){
    sm_persistent_keys_random_active = false;
    if (arg != 0){
        // key generated, store in tlv
        int status = sm_tlv_impl->store_tag(sm_tlv_context, BTSTACK_TAG32('S','M','E','R'), sm_persistent_er, 16u);
        log_info("Generated ER key. Store in TLV status: %d", status);
        UNUSED(status);
    }
    log_info_key("ER", sm_persistent_er);

    // try load ir
    int key_size = sm_tlv_impl->get_tag(sm_tlv_context, BTSTACK_TAG32('S','M','I','R'), sm_persistent_ir, 16u);
    if (key_size == 16){
        // ok, let's continue
        log_info("IR from TLV");
        sm_handle_random_result_ir( NULL );
    } else {
        // invalid, generate new random one
        sm_persistent_keys_random_active = true;
        btstack_crypto_random_generate(&sm_crypto_random_request, sm_persistent_ir, 16, &sm_handle_random_result_ir, &sm_persistent_ir);
    }
}

static void sm_connection_init(sm_connection_t * sm_conn, hci_con_handle_t con_handle, uint8_t role, uint8_t addr_type, bd_addr_t address){

    // connection info
    sm_conn->sm_handle = con_handle;
    sm_conn->sm_role = role;
    sm_conn->sm_peer_addr_type = addr_type;
    memcpy(sm_conn->sm_peer_address, address, 6);

    // security properties
    sm_conn->sm_connection_encrypted = 0;
    sm_conn->sm_connection_authenticated = 0;
    sm_conn->sm_connection_authorization_state = AUTHORIZATION_UNKNOWN;
    sm_conn->sm_le_db_index = -1;
    sm_conn->sm_reencryption_active = false;

    // prepare CSRK lookup (does not involve setup)
    sm_conn->sm_irk_lookup_state = IRK_LOOKUP_W4_READY;

    sm_conn->sm_engine_state = SM_GENERAL_IDLE;
}

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
static void sm_event_handle_classic_encryption_event(sm_connection_t * sm_conn, hci_con_handle_t con_handle){
    // CTKD requires BR/EDR Secure Connection
    if (sm_conn->sm_connection_encrypted != 2) return;
    // prepare for pairing request
    if (IS_RESPONDER(sm_conn->sm_role)){
        sm_conn->sm_engine_state = SM_BR_EDR_RESPONDER_W4_PAIRING_REQUEST;
    } else if (sm_conn->sm_pairing_requested){
        // check if remote supports fixed channels
        bool defer = true;
        const hci_connection_t * hci_connection = hci_connection_for_handle(con_handle);
        if (hci_connection->l2cap_state.information_state == L2CAP_INFORMATION_STATE_DONE){
            // check if remote supports SMP over BR/EDR
            if ((hci_connection->l2cap_state.fixed_channels_supported & (1 << L2CAP_CID_BR_EDR_SECURITY_MANAGER)) != 0){
                log_info("CTKD: SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST");
                sm_conn->sm_engine_state = SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST;
            } else {
                defer = false;
            }
        } else {
            // wait for fixed channel info
            log_info("CTKD: SM_BR_EDR_INITIATOR_W4_FIXED_CHANNEL_MASK");
            sm_conn->sm_engine_state = SM_BR_EDR_INITIATOR_W4_FIXED_CHANNEL_MASK;
        }
        if (defer){
            hci_dedicated_bonding_defer_disconnect(con_handle, true);
        }
    }
}
#endif

static void sm_event_packet_handler (uint8_t packet_type, uint16_t channel, uint8_t *packet, uint16_t size){

    UNUSED(channel);    // ok: there is no channel
    UNUSED(size);       // ok: fixed format HCI events

    sm_connection_t * sm_conn;
    hci_con_handle_t  con_handle;
    uint8_t           status;
    bd_addr_t         addr;

    switch (packet_type) {

		case HCI_EVENT_PACKET:
			switch (hci_event_packet_get_type(packet)) {

                case BTSTACK_EVENT_STATE:
                    switch (btstack_event_state_get_state(packet)){
                        case HCI_STATE_WORKING:
                            log_info("HCI Working!");
                            // setup IR/ER with TLV
                            btstack_tlv_get_instance(&sm_tlv_impl, &sm_tlv_context);
                            if (sm_tlv_impl != NULL){
                                int key_size = sm_tlv_impl->get_tag(sm_tlv_context, BTSTACK_TAG32('S','M','E','R'), sm_persistent_er, 16u);
                                if (key_size == 16){
                                    // ok, let's continue
                                    log_info("ER from TLV");
                                    sm_handle_random_result_er( NULL );
                                } else {
                                    // invalid, generate random one
                                    sm_persistent_keys_random_active = true;
                                    btstack_crypto_random_generate(&sm_crypto_random_request, sm_persistent_er, 16, &sm_handle_random_result_er, &sm_persistent_er);
                                }
                            } else {
                                sm_validate_er_ir();
                                dkg_state = DKG_CALC_IRK;

                                if (test_use_fixed_local_irk){
                                    log_info_key("IRK", sm_persistent_irk);
                                    dkg_state = DKG_CALC_DHK;
                                }
                            }

#ifdef ENABLE_LE_SECURE_CONNECTIONS
                            // trigger ECC key generation
                            if (ec_key_generation_state == EC_KEY_GENERATION_IDLE){
                                sm_ec_generate_new_key();
                            }
#endif

                            // restart random address updates after power cycle
                            if (gap_random_adress_type == GAP_RANDOM_ADDRESS_TYPE_STATIC){
                                gap_random_address_set(sm_random_address);
                            } else {
                                gap_random_address_set_mode(gap_random_adress_type);
                            }
                            break;

                        case HCI_STATE_OFF:
                        case HCI_STATE_HALTING:
                            log_info("SM: reset state");
                            // stop random address update
                            gap_random_address_update_stop();
                            // reset state
                            sm_state_reset();
                            break;

                        default:
                            break;
                    }
					break;

#ifdef ENABLE_CLASSIC
			    case HCI_EVENT_CONNECTION_COMPLETE:
			        // ignore if connection failed
			        if (hci_event_connection_complete_get_status(packet)) return;

			        con_handle = hci_event_connection_complete_get_connection_handle(packet);
			        sm_conn = sm_get_connection_for_handle(con_handle);
			        if (!sm_conn) break;

                    hci_event_connection_complete_get_bd_addr(packet, addr);
			        sm_connection_init(sm_conn,
                                       con_handle,
                                       (uint8_t) gap_get_role(con_handle),
                                       BD_ADDR_TYPE_LE_PUBLIC,
                                       addr);
			        // classic connection corresponds to public le address
			        sm_conn->sm_own_addr_type = BD_ADDR_TYPE_LE_PUBLIC;
                    gap_local_bd_addr(sm_conn->sm_own_address);
                    sm_conn->sm_cid = L2CAP_CID_BR_EDR_SECURITY_MANAGER;
                    sm_conn->sm_engine_state = SM_BR_EDR_W4_ENCRYPTION_COMPLETE;
			        break;
#endif

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
			    case HCI_EVENT_SIMPLE_PAIRING_COMPLETE:
			        if (hci_event_simple_pairing_complete_get_status(packet) != ERROR_CODE_SUCCESS) break;
                    hci_event_simple_pairing_complete_get_bd_addr(packet, addr);
                    sm_conn = sm_get_connection_for_bd_addr_and_type(addr, BD_ADDR_TYPE_ACL);
                    if (sm_conn == NULL) break;
                    sm_conn->sm_pairing_requested = 1;
			        break;
#endif

                case HCI_EVENT_LE_META:
                    switch (packet[2]) {
                        case HCI_SUBEVENT_LE_CONNECTION_COMPLETE:
                            // ignore if connection failed
                            if (packet[3]) return;

                            con_handle = little_endian_read_16(packet, 4);
                            sm_conn = sm_get_connection_for_handle(con_handle);
                            if (!sm_conn) break;

                            hci_subevent_le_connection_complete_get_peer_address(packet, addr);
                            sm_connection_init(sm_conn,
                                               con_handle,
                                               hci_subevent_le_connection_complete_get_role(packet),
                                               hci_subevent_le_connection_complete_get_peer_address_type(packet),
                                               addr);
                            sm_conn->sm_cid = L2CAP_CID_SECURITY_MANAGER_PROTOCOL;

                            // track our addr used for this connection and set state
#ifdef ENABLE_LE_PERIPHERAL
                            if (hci_subevent_le_connection_complete_get_role(packet) != 0){
                                // responder - use own address from advertisements
                                gap_le_get_own_advertisements_address(&sm_conn->sm_own_addr_type, sm_conn->sm_own_address);
                                sm_conn->sm_engine_state = SM_RESPONDER_IDLE;
                            }
#endif
#ifdef ENABLE_LE_CENTRAL
                            if (hci_subevent_le_connection_complete_get_role(packet) == 0){
                                // initiator - use own address from create connection
                                gap_le_get_own_connection_address(&sm_conn->sm_own_addr_type, sm_conn->sm_own_address);
                                sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED;
                            }
#endif
                            break;

                        case HCI_SUBEVENT_LE_LONG_TERM_KEY_REQUEST:
                            con_handle = little_endian_read_16(packet, 3);
                            sm_conn = sm_get_connection_for_handle(con_handle);
                            if (!sm_conn) break;

                            log_info("LTK Request: state %u", sm_conn->sm_engine_state);
                            if (sm_conn->sm_engine_state == SM_RESPONDER_PH2_W4_LTK_REQUEST){
                                sm_conn->sm_engine_state = SM_PH2_CALC_STK;
                                break;
                            }
                            if (sm_conn->sm_engine_state == SM_SC_W4_LTK_REQUEST_SC){
                                // PH2 SEND LTK as we need to exchange keys in PH3
                                sm_conn->sm_engine_state = SM_RESPONDER_PH2_SEND_LTK_REPLY;
                                break;
                            }

                            // store rand and ediv
                            reverse_64(&packet[5], sm_conn->sm_local_rand);
                            sm_conn->sm_local_ediv = little_endian_read_16(packet, 13);

                            // For Legacy Pairing (<=> EDIV != 0 || RAND != NULL), we need to recalculated our LTK as a
                            // potentially stored LTK is from the master
                            if ((sm_conn->sm_local_ediv != 0u) || !sm_is_null_random(sm_conn->sm_local_rand)){
                                if (sm_reconstruct_ltk_without_le_device_db_entry){
                                    sm_conn->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST;
                                    break;
                                }
                                // additionally check if remote is in LE Device DB if requested
                                switch(sm_conn->sm_irk_lookup_state){
                                    case IRK_LOOKUP_FAILED:
                                        log_info("LTK Request: device not in device db");
                                        sm_conn->sm_engine_state = SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY;
                                        break;
                                    case IRK_LOOKUP_SUCCEEDED:
                                        sm_conn->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST;
                                        break;
                                    default:
                                        // wait for irk look doen
                                        sm_conn->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_W4_IRK;
                                        break;
                                }
                                break;
                            }

#ifdef ENABLE_LE_SECURE_CONNECTIONS
                            sm_conn->sm_engine_state = SM_SC_RECEIVED_LTK_REQUEST;
#else
                            log_info("LTK Request: ediv & random are empty, but LE Secure Connections not supported");
                            sm_conn->sm_engine_state = SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY;
#endif
                            break;

                        default:
                            break;
                    }
                    break;

                case HCI_EVENT_ENCRYPTION_CHANGE:
                case HCI_EVENT_ENCRYPTION_CHANGE_V2:
                	con_handle = hci_event_encryption_change_get_connection_handle(packet);
                    sm_conn = sm_get_connection_for_handle(con_handle);
                    if (!sm_conn) break;

                    sm_conn->sm_connection_encrypted = hci_event_encryption_change_get_encryption_enabled(packet);
                    log_info("Encryption state change: %u, key size %u", sm_conn->sm_connection_encrypted,
                        sm_conn->sm_actual_encryption_key_size);
                    log_info("event handler, state %u", sm_conn->sm_engine_state);

                    switch (sm_conn->sm_engine_state){

                        case SM_PH4_W4_CONNECTION_ENCRYPTED:
                            // encryption change event concludes re-encryption for bonded devices (even if it fails)
                            if (sm_conn->sm_connection_encrypted) {
                                status = ERROR_CODE_SUCCESS;
                                if (sm_conn->sm_role){
                                    sm_conn->sm_engine_state = SM_RESPONDER_IDLE;
                                } else {
                                    sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED;
                                }
                            } else {
                                status = hci_event_encryption_change_get_status(packet);
                                // set state to 'RE-ENCRYPTION FAILED' to allow pairing but prevent other interactions
                                // also, gap_reconnect_security_setup_active will return true
                                sm_conn->sm_engine_state = SM_GENERAL_REENCRYPTION_FAILED;
                            }

                            // emit re-encryption complete
                            sm_reencryption_complete(sm_conn, status);

                            // notify client, if pairing was requested before
                            if (sm_conn->sm_pairing_requested){
                                sm_conn->sm_pairing_requested = 0;
                                sm_pairing_complete(sm_conn, status, 0);
                            }

                            sm_done_for_handle(sm_conn->sm_handle);
                            break;

                        case SM_PH2_W4_CONNECTION_ENCRYPTED:
                            if (!sm_conn->sm_connection_encrypted) break;
                            // handler for HCI_EVENT_ENCRYPTION_KEY_REFRESH_COMPLETE
                            // contains the same code for this state
                            sm_conn->sm_connection_sc = setup->sm_use_secure_connections;
                            if (IS_RESPONDER(sm_conn->sm_role)){
                                // slave
                                if (sm_conn->sm_connection_sc){
                                    sm_conn->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS;
                                } else {
                                    btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle);
                                }
                            } else {
                                // master
                                if (sm_key_distribution_all_received()){
                                    // skip receiving keys as there are none
                                    sm_key_distribution_handle_all_received(sm_conn);
                                    btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle);
                                } else {
                                    sm_conn->sm_engine_state = SM_PH3_RECEIVE_KEYS;
                                }
                            }
                            break;

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
                        case SM_BR_EDR_W4_ENCRYPTION_COMPLETE:
                            sm_event_handle_classic_encryption_event(sm_conn, con_handle);
                            break;
#endif
                        default:
                            break;
                    }
                    break;

                case HCI_EVENT_ENCRYPTION_KEY_REFRESH_COMPLETE:
                    con_handle = little_endian_read_16(packet, 3);
                    sm_conn = sm_get_connection_for_handle(con_handle);
                    if (!sm_conn) break;

                    log_info("Encryption key refresh complete, key size %u", sm_conn->sm_actual_encryption_key_size);
                    log_info("event handler, state %u", sm_conn->sm_engine_state);
                    // continue if part of initial pairing
                    switch (sm_conn->sm_engine_state){
                        case SM_PH4_W4_CONNECTION_ENCRYPTED:
                            if (sm_conn->sm_role){
                                sm_conn->sm_engine_state = SM_RESPONDER_IDLE;
                            } else {
                                sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED;
                            }
                            sm_done_for_handle(sm_conn->sm_handle);
                            break;
                        case SM_PH2_W4_CONNECTION_ENCRYPTED:
                            // handler for HCI_EVENT_ENCRYPTION_CHANGE
                            // contains the same code for this state
                            sm_conn->sm_connection_sc = setup->sm_use_secure_connections;
                            if (IS_RESPONDER(sm_conn->sm_role)){
                                // slave
                                if (sm_conn->sm_connection_sc){
                                    sm_conn->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS;
                                } else {
                                    btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle);
                                }
                            } else {
                                // master
                                if (sm_key_distribution_all_received()){
                                    // skip receiving keys as there are none
                                    sm_key_distribution_handle_all_received(sm_conn);
                                    btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle);
                                } else {
                                    sm_conn->sm_engine_state = SM_PH3_RECEIVE_KEYS;
                                }
                            }
                            break;
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
                        case SM_BR_EDR_W4_ENCRYPTION_COMPLETE:
                            sm_event_handle_classic_encryption_event(sm_conn, con_handle);
                            break;
#endif
                        default:
                            break;
                    }
                    break;


                case HCI_EVENT_DISCONNECTION_COMPLETE:
                    con_handle = little_endian_read_16(packet, 3);
                    sm_done_for_handle(con_handle);
                    sm_conn = sm_get_connection_for_handle(con_handle);
                    if (!sm_conn) break;

                    // pairing failed, if it was ongoing
                    switch (sm_conn->sm_engine_state){
                        case SM_GENERAL_IDLE:
                        case SM_INITIATOR_CONNECTED:
                        case SM_RESPONDER_IDLE:
                            break;
                        default:
                            sm_reencryption_complete(sm_conn, ERROR_CODE_REMOTE_USER_TERMINATED_CONNECTION);
                            sm_pairing_complete(sm_conn, ERROR_CODE_REMOTE_USER_TERMINATED_CONNECTION, 0);
                            break;
                    }

                    sm_conn->sm_engine_state = SM_GENERAL_IDLE;
                    sm_conn->sm_handle = 0;
                    break;

                case HCI_EVENT_COMMAND_COMPLETE:
                    if (hci_event_command_complete_get_command_opcode(packet) == HCI_OPCODE_HCI_READ_BD_ADDR) {
                        // set local addr for le device db
                        reverse_bd_addr(&packet[OFFSET_OF_DATA_IN_COMMAND_COMPLETE + 1], addr);
                        le_device_db_set_local_bd_addr(addr);
                    }
                    break;
#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
                case L2CAP_EVENT_INFORMATION_RESPONSE:
                    con_handle = l2cap_event_information_response_get_con_handle(packet);
                    sm_conn = sm_get_connection_for_handle(con_handle);
                    if (!sm_conn) break;
                    if (sm_conn->sm_engine_state == SM_BR_EDR_INITIATOR_W4_FIXED_CHANNEL_MASK){
                        // check if remote supports SMP over BR/EDR
                        const hci_connection_t * hci_connection = hci_connection_for_handle(con_handle);
                        if ((hci_connection->l2cap_state.fixed_channels_supported & (1 << L2CAP_CID_BR_EDR_SECURITY_MANAGER)) != 0){
                            sm_conn->sm_engine_state = SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST;
                        } else {
                            sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED;
                            hci_dedicated_bonding_defer_disconnect(con_handle, false);
                        }
                    }
                    break;
#endif
                default:
                    break;
			}
            break;
        default:
            break;
	}

    sm_run();
}

static inline int sm_calc_actual_encryption_key_size(int other){
    if (other < sm_min_encryption_key_size) return 0;
    if (other < sm_max_encryption_key_size) return other;
    return sm_max_encryption_key_size;
}


#ifdef ENABLE_LE_SECURE_CONNECTIONS
static int sm_just_works_or_numeric_comparison(stk_generation_method_t method){
    switch (method){
        case JUST_WORKS:
        case NUMERIC_COMPARISON:
            return 1;
        default:
            return 0;
    }
}
// responder

static int sm_passkey_used(stk_generation_method_t method){
    switch (method){
        case PK_RESP_INPUT:
            return 1;
        default:
            return 0;
    }
}

static int sm_passkey_entry(stk_generation_method_t method){
    switch (method){
        case PK_RESP_INPUT:
        case PK_INIT_INPUT:
        case PK_BOTH_INPUT:
            return 1;
        default:
            return 0;
    }
}

#endif

/**
 * @return ok
 */
static int sm_validate_stk_generation_method(void){
    // check if STK generation method is acceptable by client
    switch (setup->sm_stk_generation_method){
        case JUST_WORKS:
            return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_JUST_WORKS) != 0u;
        case PK_RESP_INPUT:
        case PK_INIT_INPUT:
        case PK_BOTH_INPUT:
            return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_PASSKEY) != 0u;
        case OOB:
            return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_OOB) != 0u;
        case NUMERIC_COMPARISON:
            return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_NUMERIC_COMPARISON) != 0u;
        default:
            return 0;
    }
}

#ifdef ENABLE_LE_CENTRAL
static void sm_initiator_connected_handle_security_request(sm_connection_t * sm_conn, const uint8_t *packet){
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    if (sm_sc_only_mode){
        uint8_t auth_req = packet[1];
        if ((auth_req & SM_AUTHREQ_SECURE_CONNECTION) == 0){
            sm_pairing_error(sm_conn, SM_REASON_AUTHENTHICATION_REQUIREMENTS);
            return;
        }
    }
#else
    UNUSED(packet);
#endif

    int have_ltk;
    uint8_t ltk[16];

    // IRK complete?
    switch (sm_conn->sm_irk_lookup_state){
        case IRK_LOOKUP_FAILED:
            // start pairing
            sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST;
            break;
        case IRK_LOOKUP_SUCCEEDED:
            le_device_db_encryption_get(sm_conn->sm_le_db_index, NULL, NULL, ltk, NULL, NULL, NULL, NULL);
            have_ltk = !sm_is_null_key(ltk);
            log_info("central: security request - have_ltk %u, encryption %u", have_ltk, sm_conn->sm_connection_encrypted);
            if (have_ltk && (sm_conn->sm_connection_encrypted == 0)){
                // start re-encrypt if we have LTK and the connection is not already encrypted
                sm_conn->sm_engine_state = SM_INITIATOR_PH4_HAS_LTK;
            } else {
                // start pairing
                sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST;
            }
            break;
        default:
            // otherwise, store security request
            sm_conn->sm_security_request_received = 1;
            break;
    }
}
#endif

static uint8_t sm_pdu_validate_and_get_opcode(uint8_t packet_type, const uint8_t *packet, uint16_t size){

    // size of complete sm_pdu used to validate input
    static const uint8_t sm_pdu_size[] = {
            0,  // 0x00 invalid opcode
            7,  // 0x01 pairing request
            7,  // 0x02 pairing response
            17, // 0x03 pairing confirm
            17, // 0x04 pairing random
            2,  // 0x05 pairing failed
            17, // 0x06 encryption information
            11, // 0x07 master identification
            17, // 0x08 identification information
            8,  // 0x09 identify address information
            17, // 0x0a signing information
            2,  // 0x0b security request
            65, // 0x0c pairing public key
            17, // 0x0d pairing dhk check
            2,  // 0x0e keypress notification
    };

    if (packet_type != SM_DATA_PACKET) return 0;
    if (size == 0u) return 0;

    uint8_t sm_pdu_code = packet[0];

    // validate pdu size
    if (sm_pdu_code >= sizeof(sm_pdu_size)) return 0;
    if (sm_pdu_size[sm_pdu_code] != size)   return 0;

    return sm_pdu_code;
}

static void sm_pdu_handler(uint8_t packet_type, hci_con_handle_t con_handle, uint8_t *packet, uint16_t size){

    if ((packet_type == HCI_EVENT_PACKET) && (packet[0] == L2CAP_EVENT_CAN_SEND_NOW)){
        sm_run();
    }

    uint8_t sm_pdu_code = sm_pdu_validate_and_get_opcode(packet_type, packet, size);
    if (sm_pdu_code == 0) return;

    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;

    if (sm_pdu_code == SM_CODE_PAIRING_FAILED){
        sm_reencryption_complete(sm_conn, ERROR_CODE_AUTHENTICATION_FAILURE);
        sm_pairing_complete(sm_conn, ERROR_CODE_AUTHENTICATION_FAILURE, packet[1]);
        sm_done_for_handle(con_handle);
        sm_conn->sm_engine_state = sm_conn->sm_role ? SM_RESPONDER_IDLE : SM_INITIATOR_CONNECTED;
        return;
    }

    log_debug("sm_pdu_handler: state %u, pdu 0x%02x", sm_conn->sm_engine_state, sm_pdu_code);

    int err;
    UNUSED(err);

    if (sm_pdu_code == SM_CODE_KEYPRESS_NOTIFICATION){
        uint8_t buffer[5];
        buffer[0] = SM_EVENT_KEYPRESS_NOTIFICATION;
        buffer[1] = 3;
        little_endian_store_16(buffer, 2, con_handle);
        buffer[4] = packet[1];
        sm_dispatch_event(HCI_EVENT_PACKET, 0, buffer, sizeof(buffer));
        return;
    }

    switch (sm_conn->sm_engine_state){

        // a sm timeout requires a new physical connection
        case SM_GENERAL_TIMEOUT:
            return;

#ifdef ENABLE_LE_CENTRAL

        // Initiator
        case SM_INITIATOR_CONNECTED:
            if ((sm_pdu_code != SM_CODE_SECURITY_REQUEST) || (sm_conn->sm_role)){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }
            sm_initiator_connected_handle_security_request(sm_conn, packet);
            break;

        case SM_INITIATOR_PH1_W4_PAIRING_RESPONSE:
            // Core 5, Vol 3, Part H, 2.4.6:
            // "The master shall ignore the slave’s Security Request if the master has sent a Pairing Request
            //  without receiving a Pairing Response from the slave or if the master has initiated encryption mode setup."
            if (sm_pdu_code == SM_CODE_SECURITY_REQUEST){
                log_info("Ignoring Security Request");
                break;
            }

            // all other pdus are incorrect
            if (sm_pdu_code != SM_CODE_PAIRING_RESPONSE){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }

            // store pairing request
            (void)memcpy(&setup->sm_s_pres, packet,
                         sizeof(sm_pairing_packet_t));
            err = sm_stk_generation_init(sm_conn);

#ifdef ENABLE_TESTING_SUPPORT
            if (0 < test_pairing_failure && test_pairing_failure < SM_REASON_DHKEY_CHECK_FAILED){
                log_info("testing_support: abort with pairing failure %u", test_pairing_failure);
                err = test_pairing_failure;
            }
#endif

            if (err != 0){
                sm_pairing_error(sm_conn, err);
                break;
            }

            // generate random number first, if we need to show passkey
            if (setup->sm_stk_generation_method == PK_RESP_INPUT){
                btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph2_tk,  (void *)(uintptr_t) sm_conn->sm_handle);
                break;
            }

#ifdef ENABLE_LE_SECURE_CONNECTIONS
            if (setup->sm_use_secure_connections){
                // SC Numeric Comparison will trigger user response after public keys & nonces have been exchanged
                if (setup->sm_stk_generation_method == JUST_WORKS){
                    sm_conn->sm_engine_state = SM_PH1_W4_USER_RESPONSE;
                    sm_trigger_user_response(sm_conn);
                    if (setup->sm_user_response == SM_USER_RESPONSE_IDLE){
                        sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND;
                    }
                } else {
                    sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND;
                }
                break;
            }
#endif
            sm_conn->sm_engine_state = SM_PH1_W4_USER_RESPONSE;
            sm_trigger_user_response(sm_conn);
            // response_idle == nothing <--> sm_trigger_user_response() did not require response
            if (setup->sm_user_response == SM_USER_RESPONSE_IDLE){
                btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle);
            }
            break;

        case SM_INITIATOR_PH2_W4_PAIRING_CONFIRM:
            if (sm_pdu_code != SM_CODE_PAIRING_CONFIRM){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }

            // store s_confirm
            reverse_128(&packet[1], setup->sm_peer_confirm);

            // abort if s_confirm matches m_confirm
            if (memcmp(setup->sm_local_confirm, setup->sm_peer_confirm, 16) == 0){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }

#ifdef ENABLE_TESTING_SUPPORT
            if (test_pairing_failure == SM_REASON_CONFIRM_VALUE_FAILED){
                log_info("testing_support: reset confirm value");
                memset(setup->sm_peer_confirm, 0, 16);
            }
#endif
            sm_conn->sm_engine_state = SM_PH2_SEND_PAIRING_RANDOM;
            break;

        case SM_INITIATOR_PH2_W4_PAIRING_RANDOM:
            if (sm_pdu_code != SM_CODE_PAIRING_RANDOM){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;;
            }

            // received random value
            reverse_128(&packet[1], setup->sm_peer_random);
            sm_conn->sm_engine_state = SM_PH2_C1_GET_ENC_C;
            break;

        case SM_PH4_W4_CONNECTION_ENCRYPTED:
            // ignore Security Request, see SM_INITIATOR_PH1_W4_PAIRING_RESPONSE above
            if (sm_pdu_code != SM_CODE_SECURITY_REQUEST){
                sm_pdu_received_in_wrong_state(sm_conn);
            }
            break;
#endif

#ifdef ENABLE_LE_PERIPHERAL
        // Responder
        case SM_RESPONDER_IDLE:
        case SM_RESPONDER_SEND_SECURITY_REQUEST:
        case SM_RESPONDER_PH1_W4_PAIRING_REQUEST:
            if (sm_pdu_code != SM_CODE_PAIRING_REQUEST){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;;
            }

            // store pairing request
            (void)memcpy(&sm_conn->sm_m_preq, packet, sizeof(sm_pairing_packet_t));

            // check if IRK completed
            switch (sm_conn->sm_irk_lookup_state){
                case IRK_LOOKUP_SUCCEEDED:
                case IRK_LOOKUP_FAILED:
                    sm_conn->sm_engine_state = SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED;
                    break;
                default:
                    sm_conn->sm_engine_state = SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED_W4_IRK;
                    break;
            }
            break;
#endif

#ifdef ENABLE_LE_SECURE_CONNECTIONS
        case SM_SC_W4_PUBLIC_KEY_COMMAND:
            if (sm_pdu_code != SM_CODE_PAIRING_PUBLIC_KEY){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }

            // store public key for DH Key calculation
            reverse_256(&packet[01], &setup->sm_peer_q[0]);
            reverse_256(&packet[33], &setup->sm_peer_q[32]);

            // CVE-2020-26558: abort pairing if remote uses the same public key
            if (memcmp(&setup->sm_peer_q, ec_q, 64) == 0){
                log_info("Remote PK matches ours");
                sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED);
                break;
            }

            // validate public key
            err = btstack_crypto_ecc_p256_validate_public_key(setup->sm_peer_q);
            if (err != 0){
                log_info("sm: peer public key invalid %x", err);
                sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED);
                break;
            }

            // start calculating dhkey
            btstack_crypto_ecc_p256_calculate_dhkey(&sm_crypto_ecc_p256_request, setup->sm_peer_q, setup->sm_dhkey, sm_sc_dhkey_calculated, (void*)(uintptr_t) sm_conn->sm_handle);


            log_info("public key received, generation method %u", setup->sm_stk_generation_method);
            if (IS_RESPONDER(sm_conn->sm_role)){
                // responder
                sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND;
            } else {
                // initiator
                // stk generation method
                // passkey entry: notify app to show passkey or to request passkey
                switch (setup->sm_stk_generation_method){
                    case JUST_WORKS:
                    case NUMERIC_COMPARISON:
                        sm_conn->sm_engine_state = SM_SC_W4_CONFIRMATION;
                        break;
                    case PK_RESP_INPUT:
                        sm_sc_start_calculating_local_confirm(sm_conn);
                        break;
                    case PK_INIT_INPUT:
                    case PK_BOTH_INPUT:
                        if (setup->sm_user_response != SM_USER_RESPONSE_PASSKEY){
                            sm_conn->sm_engine_state = SM_SC_W4_USER_RESPONSE;
                            break;
                        }
                        sm_sc_start_calculating_local_confirm(sm_conn);
                        break;
                    case OOB:
                        // generate Nx
                        log_info("Generate Na");
                        btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_send_pairing_random, (void*)(uintptr_t) sm_conn->sm_handle);
                        break;
                    default:
                        btstack_assert(false);
                        break;
                }
            }
            break;

        case SM_SC_W4_CONFIRMATION:
            if (sm_pdu_code != SM_CODE_PAIRING_CONFIRM){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }
            // received confirm value
            reverse_128(&packet[1], setup->sm_peer_confirm);

#ifdef ENABLE_TESTING_SUPPORT
            if (test_pairing_failure == SM_REASON_CONFIRM_VALUE_FAILED){
                log_info("testing_support: reset confirm value");
                memset(setup->sm_peer_confirm, 0, 16);
            }
#endif
            if (IS_RESPONDER(sm_conn->sm_role)){
                // responder
                if (sm_passkey_used(setup->sm_stk_generation_method)){
                    if (setup->sm_user_response != SM_USER_RESPONSE_PASSKEY){
                        // still waiting for passkey
                        sm_conn->sm_engine_state = SM_SC_W4_USER_RESPONSE;
                        break;
                    }
                }
                sm_sc_start_calculating_local_confirm(sm_conn);
            } else {
                // initiator
                if (sm_just_works_or_numeric_comparison(setup->sm_stk_generation_method)){
                    btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_send_pairing_random, (void*)(uintptr_t) sm_conn->sm_handle);
                } else {
                    sm_conn->sm_engine_state = SM_SC_SEND_PAIRING_RANDOM;
                }
            }
            break;

        case SM_SC_W4_PAIRING_RANDOM:
            if (sm_pdu_code != SM_CODE_PAIRING_RANDOM){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }

            // received random value
            reverse_128(&packet[1], setup->sm_peer_nonce);

            // validate confirm value if Cb = f4(Pkb, Pka, Nb, z)
            // only check for JUST WORK/NC in initiator role OR passkey entry
            log_info("SM_SC_W4_PAIRING_RANDOM, responder: %u, just works: %u, passkey used %u, passkey entry %u",
                     IS_RESPONDER(sm_conn->sm_role), sm_just_works_or_numeric_comparison(setup->sm_stk_generation_method),
                     sm_passkey_used(setup->sm_stk_generation_method), sm_passkey_entry(setup->sm_stk_generation_method));
            if ( (!IS_RESPONDER(sm_conn->sm_role) && sm_just_works_or_numeric_comparison(setup->sm_stk_generation_method))
            ||   (sm_passkey_entry(setup->sm_stk_generation_method)) ) {
                 sm_conn->sm_engine_state = SM_SC_W2_CMAC_FOR_CHECK_CONFIRMATION;
                 break;
            }

            // OOB
            if (setup->sm_stk_generation_method == OOB){

                // setup local random, set to zero if remote did not receive our data
                log_info("Received nonce, setup local random ra/rb for dhkey check");
                if (IS_RESPONDER(sm_conn->sm_role)){
                    if (sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq) == 0u){
                        log_info("Reset rb as A does not have OOB data");
                        memset(setup->sm_rb, 0, 16);
                    } else {
                        (void)memcpy(setup->sm_rb, sm_sc_oob_random, 16);
                        log_info("Use stored rb");
                        log_info_hexdump(setup->sm_rb, 16);
                    }
                }  else {
                    if (sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres) == 0u){
                        log_info("Reset ra as B does not have OOB data");
                        memset(setup->sm_ra, 0, 16);
                    } else {
                        (void)memcpy(setup->sm_ra, sm_sc_oob_random, 16);
                        log_info("Use stored ra");
                        log_info_hexdump(setup->sm_ra, 16);
                    }
                }

                // validate confirm value if Cb = f4(PKb, Pkb, rb, 0) for OOB if data received
                if (setup->sm_have_oob_data){
                     sm_conn->sm_engine_state = SM_SC_W2_CMAC_FOR_CHECK_CONFIRMATION;
                     break;
                }
            }

            // TODO: we only get here for Responder role with JW/NC
            sm_sc_state_after_receiving_random(sm_conn);
            break;

        case SM_SC_W2_CALCULATE_G2:
        case SM_SC_W4_CALCULATE_G2:
        case SM_SC_W4_CALCULATE_DHKEY:
        case SM_SC_W2_CALCULATE_F5_SALT:
        case SM_SC_W4_CALCULATE_F5_SALT:
        case SM_SC_W2_CALCULATE_F5_MACKEY:
        case SM_SC_W4_CALCULATE_F5_MACKEY:
        case SM_SC_W2_CALCULATE_F5_LTK:
        case SM_SC_W4_CALCULATE_F5_LTK:
        case SM_SC_W2_CALCULATE_F6_FOR_DHKEY_CHECK:
        case SM_SC_W4_DHKEY_CHECK_COMMAND:
        case SM_SC_W4_CALCULATE_F6_FOR_DHKEY_CHECK:
        case SM_SC_W4_USER_RESPONSE:
            if (sm_pdu_code != SM_CODE_PAIRING_DHKEY_CHECK){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }
            // store DHKey Check
            setup->sm_state_vars |= SM_STATE_VAR_DHKEY_COMMAND_RECEIVED;
            reverse_128(&packet[01], setup->sm_peer_dhkey_check);

            // have we been only waiting for dhkey check command?
            if (sm_conn->sm_engine_state == SM_SC_W4_DHKEY_CHECK_COMMAND){
                sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK;
            }
            break;
#endif

#ifdef ENABLE_LE_PERIPHERAL
        case SM_RESPONDER_PH1_W4_PAIRING_CONFIRM:
            if (sm_pdu_code != SM_CODE_PAIRING_CONFIRM){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }

            // received confirm value
            reverse_128(&packet[1], setup->sm_peer_confirm);

#ifdef ENABLE_TESTING_SUPPORT
            if (test_pairing_failure == SM_REASON_CONFIRM_VALUE_FAILED){
                log_info("testing_support: reset confirm value");
                memset(setup->sm_peer_confirm, 0, 16);
            }
#endif
            // notify client to hide shown passkey
            if (setup->sm_stk_generation_method == PK_INIT_INPUT){
                sm_notify_client_base(SM_EVENT_PASSKEY_DISPLAY_CANCEL, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address);
            }

            // handle user cancel pairing?
            if (setup->sm_user_response == SM_USER_RESPONSE_DECLINE){
                sm_pairing_error(sm_conn, SM_REASON_PASSKEY_ENTRY_FAILED);
                break;
            }

            // wait for user action?
            if (setup->sm_user_response == SM_USER_RESPONSE_PENDING){
                sm_conn->sm_engine_state = SM_PH1_W4_USER_RESPONSE;
                break;
            }

            // calculate and send local_confirm
            btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle);
            break;

        case SM_RESPONDER_PH2_W4_PAIRING_RANDOM:
            if (sm_pdu_code != SM_CODE_PAIRING_RANDOM){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;;
            }

            // received random value
            reverse_128(&packet[1], setup->sm_peer_random);
            sm_conn->sm_engine_state = SM_PH2_C1_GET_ENC_C;
            break;
#endif

        case SM_PH2_W4_CONNECTION_ENCRYPTED:
        case SM_PH3_RECEIVE_KEYS:
            switch(sm_pdu_code){
                case SM_CODE_ENCRYPTION_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION;
                    reverse_128(&packet[1], setup->sm_peer_ltk);
                    break;

                case SM_CODE_MASTER_IDENTIFICATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_MASTER_IDENTIFICATION;
                    setup->sm_peer_ediv = little_endian_read_16(packet, 1);
                    reverse_64(&packet[3], setup->sm_peer_rand);
                    break;

                case SM_CODE_IDENTITY_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION;
                    reverse_128(&packet[1], setup->sm_peer_irk);
                    break;

                case SM_CODE_IDENTITY_ADDRESS_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION;
                    setup->sm_peer_addr_type = packet[1];
                    reverse_bd_addr(&packet[2], setup->sm_peer_address);
                    break;

                case SM_CODE_SIGNING_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION;
                    reverse_128(&packet[1], setup->sm_peer_csrk);
                    break;
                default:
                    // Unexpected PDU
                    log_info("Unexpected PDU %u in SM_PH3_RECEIVE_KEYS", packet[0]);
                    break;
            }
            // done with key distribution?
            if (sm_key_distribution_all_received()){

                sm_key_distribution_handle_all_received(sm_conn);

                if (IS_RESPONDER(sm_conn->sm_role)){
                    sm_key_distribution_complete_responder(sm_conn);
                } else {
                    if (setup->sm_use_secure_connections){
                        sm_conn->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS;
                    } else {
                        btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle);
                    }
                }
            }
            break;

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION

        case SM_BR_EDR_W4_ENCRYPTION_COMPLETE:
            // GAP/DM/LEP/BI-02-C - reject CTKD if P-192 encryption is used
            if (sm_pdu_code == SM_CODE_PAIRING_REQUEST){
                sm_pairing_error(sm_conn, SM_REASON_CROSS_TRANSPORT_KEY_DERIVATION_NOT_ALLOWED);
            }
            break;

        case SM_BR_EDR_INITIATOR_W4_PAIRING_RESPONSE:

            // dedicated bonding complete
            hci_dedicated_bonding_defer_disconnect(sm_conn->sm_handle, false);

            if (sm_pdu_code != SM_CODE_PAIRING_RESPONSE){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }
            // store pairing response
            (void)memcpy(&setup->sm_s_pres, packet, sizeof(sm_pairing_packet_t));

            // validate encryption key size
            sm_conn->sm_actual_encryption_key_size = sm_calc_actual_encryption_key_size(sm_pairing_packet_get_max_encryption_key_size(setup->sm_s_pres));
            // SC Only mandates 128 bit key size
            if (sm_sc_only_mode && (sm_conn->sm_actual_encryption_key_size < 16)) {
                sm_conn->sm_actual_encryption_key_size  = 0;
            }
            if (sm_conn->sm_actual_encryption_key_size == 0){
                sm_pairing_error(sm_conn, SM_REASON_ENCRYPTION_KEY_SIZE);
                break;
            }

            // prepare key exchange, LTK is derived locally
            sm_setup_key_distribution(sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres) & ~SM_KEYDIST_ENC_KEY,
                                      sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres) & ~SM_KEYDIST_ENC_KEY);

            // skip receive if there are none
            if (sm_key_distribution_all_received()){
                // distribute keys in run handles 'no keys to send'
                sm_conn->sm_engine_state = SM_BR_EDR_DISTRIBUTE_KEYS;
            } else {
                sm_conn->sm_engine_state = SM_BR_EDR_RECEIVE_KEYS;
            }
            break;

        case SM_BR_EDR_RESPONDER_W4_PAIRING_REQUEST:
            if (sm_pdu_code != SM_CODE_PAIRING_REQUEST){
                sm_pdu_received_in_wrong_state(sm_conn);
                break;
            }
            // store pairing request
            (void)memcpy(&sm_conn->sm_m_preq, packet, sizeof(sm_pairing_packet_t));
            // validate encryption key size
            sm_conn->sm_actual_encryption_key_size = sm_calc_actual_encryption_key_size(sm_pairing_packet_get_max_encryption_key_size(sm_conn->sm_m_preq));
            // SC Only mandates 128 bit key size
            if (sm_sc_only_mode && (sm_conn->sm_actual_encryption_key_size < 16)) {
                sm_conn->sm_actual_encryption_key_size  = 0;
            }
            if (sm_conn->sm_actual_encryption_key_size == 0){
                sm_pairing_error(sm_conn, SM_REASON_ENCRYPTION_KEY_SIZE);
                break;
            }
            // trigger response
            if (sm_ctkd_from_classic(sm_conn)){
                sm_conn->sm_engine_state = SM_BR_EDR_RESPONDER_PAIRING_REQUEST_RECEIVED;
            } else {
                sm_pairing_error(sm_conn, SM_REASON_CROSS_TRANSPORT_KEY_DERIVATION_NOT_ALLOWED);
            }
            break;

        case SM_BR_EDR_RECEIVE_KEYS:
            switch(sm_pdu_code){
                case SM_CODE_IDENTITY_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION;
                    reverse_128(&packet[1], setup->sm_peer_irk);
                    break;
                case SM_CODE_IDENTITY_ADDRESS_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION;
                    setup->sm_peer_addr_type = packet[1];
                    reverse_bd_addr(&packet[2], setup->sm_peer_address);
                    break;
                case SM_CODE_SIGNING_INFORMATION:
                    setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION;
                    reverse_128(&packet[1], setup->sm_peer_csrk);
                    break;
                default:
                    // Unexpected PDU
                    log_info("Unexpected PDU %u in SM_PH3_RECEIVE_KEYS", packet[0]);
                    break;
            }

            // all keys received
            if (sm_key_distribution_all_received()){
                if (IS_RESPONDER(sm_conn->sm_role)){
                    // responder -> keys exchanged, derive LE LTK
                    sm_ctkd_start_from_br_edr(sm_conn);
                } else {
                    // initiator -> send our keys if any
                    sm_conn->sm_engine_state = SM_BR_EDR_DISTRIBUTE_KEYS;
                }
            }
            break;
#endif

        default:
            // Unexpected PDU
            log_info("Unexpected PDU %u in state %u", packet[0], sm_conn->sm_engine_state);
            sm_pdu_received_in_wrong_state(sm_conn);
            break;
    }

    // try to send next pdu
    sm_trigger_run();
}

// Security Manager Client API
void sm_register_oob_data_callback( int (*get_oob_data_callback)(uint8_t address_type, bd_addr_t addr, uint8_t * oob_data)){
    sm_get_oob_data = get_oob_data_callback;
}

void sm_register_sc_oob_data_callback( int (*get_sc_oob_data_callback)(uint8_t address_type, bd_addr_t addr, uint8_t * oob_sc_peer_confirm, uint8_t * oob_sc_peer_random)){
    sm_get_sc_oob_data = get_sc_oob_data_callback;
}

void sm_register_ltk_callback( bool (*get_ltk_callback)(hci_con_handle_t con_handle, uint8_t address_type, bd_addr_t addr, uint8_t * ltk)){
    sm_get_ltk_callback = get_ltk_callback;
}

void sm_add_event_handler(btstack_packet_callback_registration_t * callback_handler){
    btstack_linked_list_add_tail(&sm_event_handlers, (btstack_linked_item_t*) callback_handler);
}

void sm_remove_event_handler(btstack_packet_callback_registration_t * callback_handler){
    btstack_linked_list_remove(&sm_event_handlers, (btstack_linked_item_t*) callback_handler);
}

void sm_set_accepted_stk_generation_methods(uint8_t accepted_stk_generation_methods){
    sm_accepted_stk_generation_methods = accepted_stk_generation_methods;
}

void sm_set_encryption_key_size_range(uint8_t min_size, uint8_t max_size){
	sm_min_encryption_key_size = min_size;
	sm_max_encryption_key_size = max_size;
}

void sm_set_authentication_requirements(uint8_t auth_req){
#ifndef ENABLE_LE_SECURE_CONNECTIONS
    if (auth_req & SM_AUTHREQ_SECURE_CONNECTION){
        log_error("ENABLE_LE_SECURE_CONNECTIONS not defined, but requested by app. Dropping SC flag");
        auth_req &= ~SM_AUTHREQ_SECURE_CONNECTION;
    }
#endif
    sm_auth_req = auth_req;
}

void sm_set_io_capabilities(io_capability_t io_capability){
    sm_io_capabilities = io_capability;
}

#ifdef ENABLE_LE_PERIPHERAL
void sm_set_request_security(int enable){
    sm_slave_request_security = enable;
}
#endif

void sm_set_er(sm_key_t er){
    (void)memcpy(sm_persistent_er, er, 16);
}

void sm_set_ir(sm_key_t ir){
    (void)memcpy(sm_persistent_ir, ir, 16);
}

// Testing support only
void sm_test_set_irk(sm_key_t irk){
    (void)memcpy(sm_persistent_irk, irk, 16);
    dkg_state = DKG_CALC_DHK;
    test_use_fixed_local_irk = true;
}

void sm_test_use_fixed_local_csrk(void){
    test_use_fixed_local_csrk = true;
}

#ifdef ENABLE_LE_SECURE_CONNECTIONS
static void sm_ec_generated(void * arg){
    UNUSED(arg);
    ec_key_generation_state = EC_KEY_GENERATION_DONE;
    // trigger pairing if pending for ec key
    sm_trigger_run();
}
static void sm_ec_generate_new_key(void){
    log_info("sm: generate new ec key");
    ec_key_generation_state = EC_KEY_GENERATION_ACTIVE;
    btstack_crypto_ecc_p256_generate_key(&sm_crypto_ecc_p256_request, ec_q, &sm_ec_generated, NULL);
}
#endif

#ifdef ENABLE_TESTING_SUPPORT
void sm_test_set_pairing_failure(int reason){
    test_pairing_failure = reason;
}
#endif

static void sm_state_reset(void) {
#ifdef USE_CMAC_ENGINE
    sm_cmac_active  = 0;
#endif
    dkg_state = DKG_W4_WORKING;
    rau_state = RAU_IDLE;
    sm_aes128_state = SM_AES128_IDLE;
    sm_address_resolution_test = -1;    // no private address to resolve yet
    sm_address_resolution_mode = ADDRESS_RESOLUTION_IDLE;
    sm_address_resolution_general_queue = NULL;
    sm_active_connection_handle = HCI_CON_HANDLE_INVALID;
    sm_persistent_keys_random_active = false;
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    ec_key_generation_state = EC_KEY_GENERATION_IDLE;
#endif
}

void sm_init(void){

    if (sm_initialized) return;

    // set default ER and IR values (should be unique - set by app or sm later using TLV)
    sm_er_ir_set_default();

    // defaults
    sm_accepted_stk_generation_methods = SM_STK_GENERATION_METHOD_JUST_WORKS
                                       | SM_STK_GENERATION_METHOD_OOB
                                       | SM_STK_GENERATION_METHOD_PASSKEY
                                       | SM_STK_GENERATION_METHOD_NUMERIC_COMPARISON;

    sm_max_encryption_key_size = 16;
    sm_min_encryption_key_size = 7;

    sm_fixed_passkey_in_display_role = 0xffffffffU;
    sm_reconstruct_ltk_without_le_device_db_entry = true;

    gap_random_adress_update_period = 15 * 60 * 1000L;

    test_use_fixed_local_csrk = false;

    // other
    btstack_run_loop_set_timer_handler(&sm_run_timer, &sm_run_timer_handler);

    // register for HCI Events
    hci_event_callback_registration.callback = &sm_event_packet_handler;
    hci_add_event_handler(&hci_event_callback_registration);

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
    // register for L2CAP events
    l2cap_event_callback_registration.callback = &sm_event_packet_handler;
    l2cap_add_event_handler(&l2cap_event_callback_registration);
#endif

    //
    btstack_crypto_init();

    // init le_device_db
    le_device_db_init();

    // and L2CAP PDUs + L2CAP_EVENT_CAN_SEND_NOW
    l2cap_register_fixed_channel(sm_pdu_handler, L2CAP_CID_SECURITY_MANAGER_PROTOCOL);
#ifdef ENABLE_CLASSIC
    l2cap_register_fixed_channel(sm_pdu_handler, L2CAP_CID_BR_EDR_SECURITY_MANAGER);
#endif

    // state
    sm_state_reset();

    sm_initialized = true;
}

void sm_deinit(void){
    sm_initialized = false;
    btstack_run_loop_remove_timer(&sm_run_timer);
}

void sm_use_fixed_passkey_in_display_role(uint32_t passkey){
    sm_fixed_passkey_in_display_role = passkey;
}

void sm_allow_ltk_reconstruction_without_le_device_db_entry(int allow){
    sm_reconstruct_ltk_without_le_device_db_entry = allow != 0;
}

static sm_connection_t * sm_get_connection_for_handle(hci_con_handle_t con_handle){
    hci_connection_t * hci_con = hci_connection_for_handle(con_handle);
    if (!hci_con) return NULL;
    return &hci_con->sm_connection;
}

static void sm_cache_ltk(sm_connection_t * connection, const sm_key_t ltk){
    hci_connection_t * hci_con = hci_connection_for_handle(connection->sm_handle);
    btstack_assert(hci_con != NULL);
    memcpy(hci_con->link_key, ltk, 16);
    hci_con->link_key_type = 1;
}

#ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION
static sm_connection_t * sm_get_connection_for_bd_addr_and_type(bd_addr_t address, bd_addr_type_t addr_type){
    hci_connection_t * hci_con = hci_connection_for_bd_addr_and_type(address, addr_type);
    if (!hci_con) return NULL;
    return &hci_con->sm_connection;
}
#endif

// @deprecated: map onto sm_request_pairing
void sm_send_security_request(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;
    if (!IS_RESPONDER(sm_conn->sm_role)) return;
    sm_request_pairing(con_handle);
}

// request pairing
void sm_request_pairing(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection

    bool have_ltk;
    uint8_t ltk[16];
    bool auth_required;
    int authenticated;
    bool trigger_reencryption;
    log_info("sm_request_pairing in role %u, state %u", sm_conn->sm_role, sm_conn->sm_engine_state);
    if (IS_RESPONDER(sm_conn->sm_role)){
        switch (sm_conn->sm_engine_state){
            case SM_GENERAL_IDLE:
            case SM_RESPONDER_IDLE:
                switch (sm_conn->sm_irk_lookup_state){
                    case IRK_LOOKUP_SUCCEEDED:
                        le_device_db_encryption_get(sm_conn->sm_le_db_index, NULL, NULL, ltk, NULL, NULL, NULL, NULL);
                        have_ltk = !sm_is_null_key(ltk);
                        log_info("have ltk %u", have_ltk);
                        if (have_ltk){
                            sm_conn->sm_pairing_requested = 1;
                            sm_conn->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST;
                            sm_reencryption_started(sm_conn);
                            break;
                        }
                        /* fall through */

                    case IRK_LOOKUP_FAILED:
                        sm_conn->sm_pairing_requested = 1;
                        sm_conn->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST;
                        sm_pairing_started(sm_conn);
                        break;
                    default:
                        log_info("irk lookup pending");
                        sm_conn->sm_pairing_requested = 1;
                        break;
                }
                break;
            default:
                break;
        }
    } else {
        // used as a trigger to start central/master/initiator security procedures
        switch (sm_conn->sm_engine_state){
            case SM_INITIATOR_CONNECTED:
                switch (sm_conn->sm_irk_lookup_state){
                    case IRK_LOOKUP_SUCCEEDED:
                        le_device_db_encryption_get(sm_conn->sm_le_db_index, NULL, NULL, ltk, NULL, &authenticated, NULL, NULL);
                        have_ltk = !sm_is_null_key(ltk);
                        auth_required = sm_auth_req & SM_AUTHREQ_MITM_PROTECTION;
                        // re-encrypt is sufficient if we have ltk and that is either already authenticated or we don't require authentication
                        trigger_reencryption = have_ltk && ((authenticated != 0) || (auth_required == false));
                        log_info("have ltk %u, authenticated %u, auth required %u => reencrypt %u", have_ltk, authenticated, auth_required, trigger_reencryption);
                        if (trigger_reencryption){
                            sm_conn->sm_pairing_requested = 1;
                            sm_conn->sm_engine_state = SM_INITIATOR_PH4_HAS_LTK;
                            break;
                        }
                        /* fall through */

                    case IRK_LOOKUP_FAILED:
                        sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST;
                        break;
                    default:
                        log_info("irk lookup pending");
                        sm_conn->sm_pairing_requested = 1;
                        break;
                }
                break;
            case SM_GENERAL_REENCRYPTION_FAILED:
                sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST;
                break;
            case SM_GENERAL_IDLE:
                sm_conn->sm_pairing_requested = 1;
                break;
            default:
                break;
        }
    }
    sm_trigger_run();
}

// called by client app on authorization request
void sm_authorization_decline(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection
    sm_conn->sm_connection_authorization_state = AUTHORIZATION_DECLINED;
    sm_notify_client_status(SM_EVENT_AUTHORIZATION_RESULT, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address, 0);
}

void sm_authorization_grant(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection
    sm_conn->sm_connection_authorization_state = AUTHORIZATION_GRANTED;
    sm_notify_client_status(SM_EVENT_AUTHORIZATION_RESULT, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address, 1);
}

// GAP Bonding API

void sm_bonding_decline(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection
    setup->sm_user_response = SM_USER_RESPONSE_DECLINE;
    log_info("decline, state %u", sm_conn->sm_engine_state);
    switch(sm_conn->sm_engine_state){
#ifdef ENABLE_LE_SECURE_CONNECTIONS
        case SM_SC_W4_USER_RESPONSE:
        case SM_SC_W4_CONFIRMATION:
        case SM_SC_W4_PUBLIC_KEY_COMMAND:
#endif
        case SM_PH1_W4_USER_RESPONSE:
            switch (setup->sm_stk_generation_method){
                case PK_RESP_INPUT:
                case PK_INIT_INPUT:
                case PK_BOTH_INPUT:
                    sm_pairing_error(sm_conn, SM_REASON_PASSKEY_ENTRY_FAILED);
                    break;
                case NUMERIC_COMPARISON:
                    sm_pairing_error(sm_conn, SM_REASON_NUMERIC_COMPARISON_FAILED);
                    break;
                case JUST_WORKS:
                case OOB:
                    sm_pairing_error(sm_conn, SM_REASON_UNSPECIFIED_REASON);
                    break;
                default:
                    btstack_assert(false);
                    break;
            }
            break;
        default:
            break;
    }
    sm_trigger_run();
}

void sm_just_works_confirm(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection
    setup->sm_user_response = SM_USER_RESPONSE_CONFIRM;
    if (sm_conn->sm_engine_state == SM_PH1_W4_USER_RESPONSE){
        if (setup->sm_use_secure_connections){
            sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND;
        } else {
            btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle);
        }
    }

#ifdef ENABLE_LE_SECURE_CONNECTIONS
    if (sm_conn->sm_engine_state == SM_SC_W4_USER_RESPONSE){
        sm_sc_prepare_dhkey_check(sm_conn);
    }
#endif

    sm_trigger_run();
}

void sm_numeric_comparison_confirm(hci_con_handle_t con_handle){
    // for now, it's the same
    sm_just_works_confirm(con_handle);
}

void sm_passkey_input(hci_con_handle_t con_handle, uint32_t passkey){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection
    sm_reset_tk();
    big_endian_store_32(setup->sm_tk, 12, passkey);
    setup->sm_user_response = SM_USER_RESPONSE_PASSKEY;
    if (sm_conn->sm_engine_state == SM_PH1_W4_USER_RESPONSE){
        btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle);
    }
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    (void)memcpy(setup->sm_ra, setup->sm_tk, 16);
    (void)memcpy(setup->sm_rb, setup->sm_tk, 16);
    if (sm_conn->sm_engine_state == SM_SC_W4_USER_RESPONSE){
        sm_sc_start_calculating_local_confirm(sm_conn);
    }
#endif
    sm_trigger_run();
}

void sm_keypress_notification(hci_con_handle_t con_handle, uint8_t action){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return;     // wrong connection
    if (action > SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED) return;
    uint8_t num_actions = setup->sm_keypress_notification >> 5;
    uint8_t flags = setup->sm_keypress_notification & 0x1fu;
    switch (action){
        case SM_KEYPRESS_PASSKEY_ENTRY_STARTED:
        case SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED:
            flags |= (1u << action);
            break;
        case SM_KEYPRESS_PASSKEY_CLEARED:
            // clear counter, keypress & erased flags + set passkey cleared
            flags = (flags & 0x19u) | (1u << SM_KEYPRESS_PASSKEY_CLEARED);
            break;
        case SM_KEYPRESS_PASSKEY_DIGIT_ENTERED:
            if (flags & (1u << SM_KEYPRESS_PASSKEY_DIGIT_ERASED)){
                // erase actions queued
                num_actions--;
                if (num_actions == 0u){
                    // clear counter, keypress & erased flags
                    flags &= 0x19u;
                }
                break;
            }
            num_actions++;
            flags |= (1u << SM_KEYPRESS_PASSKEY_DIGIT_ENTERED);
            break;
        case SM_KEYPRESS_PASSKEY_DIGIT_ERASED:
            if (flags & (1u << SM_KEYPRESS_PASSKEY_DIGIT_ENTERED)){
                // enter actions queued
                num_actions--;
                if (num_actions == 0u){
                    // clear counter, keypress & erased flags
                    flags &= 0x19u;
                }
                break;
            }
            num_actions++;
            flags |= (1u << SM_KEYPRESS_PASSKEY_DIGIT_ERASED);
            break;
        default:
            break;
    }
    setup->sm_keypress_notification = (num_actions << 5) | flags;
    sm_trigger_run();
}

#ifdef ENABLE_LE_SECURE_CONNECTIONS
static void sm_handle_random_result_oob(void * arg){
    UNUSED(arg);
    sm_sc_oob_state = SM_SC_OOB_W2_CALC_CONFIRM;
    sm_trigger_run();
}
uint8_t sm_generate_sc_oob_data(void (*callback)(const uint8_t * confirm_value, const uint8_t * random_value)){

    static btstack_crypto_random_t   sm_crypto_random_oob_request;

    if (sm_sc_oob_state != SM_SC_OOB_IDLE) return ERROR_CODE_COMMAND_DISALLOWED;
    sm_sc_oob_callback = callback;
    sm_sc_oob_state = SM_SC_OOB_W4_RANDOM;
    btstack_crypto_random_generate(&sm_crypto_random_oob_request, sm_sc_oob_random, 16, &sm_handle_random_result_oob, NULL);
    return 0;
}
#endif

/**
 * @brief Get Identity Resolving state
 * @param con_handle
 * @return irk_lookup_state_t
 */
irk_lookup_state_t sm_identity_resolving_state(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return IRK_LOOKUP_IDLE;
    return sm_conn->sm_irk_lookup_state;
}

/**
 * @brief Identify device in LE Device DB
 * @param handle
 * @return index from le_device_db or -1 if not found/identified
 */
int sm_le_device_index(hci_con_handle_t con_handle ){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
    if (!sm_conn) return -1;
    return sm_conn->sm_le_db_index;
}

uint8_t sm_get_ltk(hci_con_handle_t con_handle, sm_key_t ltk){
    hci_connection_t * hci_connection = hci_connection_for_handle(con_handle);
    if (hci_connection == NULL){
        return ERROR_CODE_UNKNOWN_CONNECTION_IDENTIFIER;
    }
    if (hci_connection->link_key_type == 0){
        return ERROR_CODE_PIN_OR_KEY_MISSING;
    }
    memcpy(ltk, hci_connection->link_key, 16);
    return ERROR_CODE_SUCCESS;
}

static int gap_random_address_type_requires_updates(void){
    switch (gap_random_adress_type){
        case GAP_RANDOM_ADDRESS_TYPE_OFF:
        case GAP_RANDOM_ADDRESS_TYPE_STATIC:
            return 0;
        default:
            return 1;
    }
}

static uint8_t own_address_type(void){
    switch (gap_random_adress_type){
        case GAP_RANDOM_ADDRESS_TYPE_OFF:
            return BD_ADDR_TYPE_LE_PUBLIC;
        default:
            return BD_ADDR_TYPE_LE_RANDOM;
    }
}

// GAP LE API
void gap_random_address_set_mode(gap_random_address_type_t random_address_type){
    gap_random_address_update_stop();
    gap_random_adress_type = random_address_type;
    hci_le_set_own_address_type(own_address_type());
    if (!gap_random_address_type_requires_updates()) return;
    gap_random_address_update_start();
    gap_random_address_trigger();
}

gap_random_address_type_t gap_random_address_get_mode(void){
    return gap_random_adress_type;
}

void gap_random_address_set_update_period(int period_ms){
    gap_random_adress_update_period = period_ms;
    if (!gap_random_address_type_requires_updates()) return;
    gap_random_address_update_stop();
    gap_random_address_update_start();
}

void gap_random_address_set(const bd_addr_t addr){
    gap_random_address_set_mode(GAP_RANDOM_ADDRESS_TYPE_STATIC);
    (void)memcpy(sm_random_address, addr, 6);
    // assert msb bits are set to '11'
    sm_random_address[0] |= 0xc0;
    hci_le_random_address_set(sm_random_address);
}

#ifdef ENABLE_LE_PERIPHERAL
/*
 * @brief Set Advertisement Paramters
 * @param adv_int_min
 * @param adv_int_max
 * @param adv_type
 * @param direct_address_type
 * @param direct_address
 * @param channel_map
 * @param filter_policy
 *
 * @note own_address_type is used from gap_random_address_set_mode
 */
void gap_advertisements_set_params(uint16_t adv_int_min, uint16_t adv_int_max, uint8_t adv_type,
    uint8_t direct_address_typ, bd_addr_t direct_address, uint8_t channel_map, uint8_t filter_policy){
    hci_le_advertisements_set_params(adv_int_min, adv_int_max, adv_type,
        direct_address_typ, direct_address, channel_map, filter_policy);
}
#endif

int gap_reconnect_security_setup_active(hci_con_handle_t con_handle){
    sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle);
     // wrong connection
    if (!sm_conn) return 0;
    // already encrypted
    if (sm_conn->sm_connection_encrypted) return 0;
    // irk status?
    switch(sm_conn->sm_irk_lookup_state){
        case IRK_LOOKUP_FAILED:
            // done, cannot setup encryption
            return 0;
        case IRK_LOOKUP_SUCCEEDED:
            break;
        default:
            // IR Lookup pending
            return 1;
    }
    // IRK Lookup Succeeded, re-encryption should be initiated. When done, state gets reset or indicates failure
    if (sm_conn->sm_engine_state == SM_GENERAL_REENCRYPTION_FAILED) return 0;
    if (sm_conn->sm_role){
        return sm_conn->sm_engine_state != SM_RESPONDER_IDLE;
    } else {
        return sm_conn->sm_engine_state != SM_INITIATOR_CONNECTED;
    }
}

void sm_set_secure_connections_only_mode(bool enable){
#ifdef ENABLE_LE_SECURE_CONNECTIONS
    sm_sc_only_mode = enable;
#else
    // SC Only mode not possible without support for SC
    btstack_assert(enable == false);
#endif
}

const uint8_t * gap_get_persistent_irk(void){
    return sm_persistent_irk;
}

void gap_delete_bonding(bd_addr_type_t address_type, bd_addr_t address){
    int index = sm_le_device_db_index_lookup(address_type, address);
    if (index >= 0){
        sm_remove_le_device_db_entry(index);
    }
}