CANopen.c

/*
 * Main CANopenNode file.
 *
 * @file        CANopen.c
 * @ingroup     CO_CANopen
 * @author      Janez Paternoster
 * @copyright   2010 - 2023 Janez Paternoster
 *
 * This file is part of CANopenNode, an opensource CANopen Stack.
 * Project home page is <https://github.com/CANopenNode/CANopenNode>.
 * For more information on CANopen see <http://www.can-cia.org/>.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#include "CANopen.h"

/* Get values from CO_config_t or from single default OD.h ********************/
#ifdef CO_MULTIPLE_OD
#define CO_GET_CO(obj) co->obj
#define CO_GET_CNT(obj) co->config->CNT_##obj
#define OD_GET(entry, index) co->config->ENTRY_##entry

#else
#include "OD.h"
#define CO_GET_CO(obj) CO_##obj
#define CO_GET_CNT(obj) OD_CNT_##obj
#define OD_GET(entry, index) OD_ENTRY_##entry

/* Verify parameters from "OD.h" and calculate necessary values for each object:
 * - verify OD_CNT_xx or set default
 * - calculate number of CANrx and CYNtx messages: CO_RX_CNT_xx and CO_TX_CNT_xx
 * - set optional undefined OD_ENTRY_Hxxxx to NULL.
 * - calculate indexes: CO_RX_IDX_xx and CO_TX_IDX_xx
 * - calculate total count of CAN message buffers: CO_CNT_ALL_RX_MSGS and
 *   CO_CNT_ALL_TX_MSGS. */
#if OD_CNT_NMT != 1
 #error OD_CNT_NMT from OD.h not correct!
#endif
#define CO_RX_CNT_NMT_SLV OD_CNT_NMT
#if (CO_CONFIG_NMT) & CO_CONFIG_NMT_MASTER
 #define CO_TX_CNT_NMT_MST 1
#else
 #define CO_TX_CNT_NMT_MST 0
#endif

#if OD_CNT_HB_PROD != 1
 #error OD_CNT_HB_PROD from OD.h not correct!
#endif
#define CO_TX_CNT_HB_PROD OD_CNT_HB_PROD
#if !defined OD_CNT_HB_CONS
 #define OD_CNT_HB_CONS 0
#elif OD_CNT_HB_CONS < 0 || OD_CNT_HB_CONS > 1
 #error OD_CNT_HB_CONS from OD.h not correct!
#endif
#if ((CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE) && OD_CNT_HB_CONS == 1
 #if OD_CNT_ARR_1016 < 1 || OD_CNT_ARR_1016 > 127
  #error OD_CNT_ARR_1016 is not defined in Object Dictionary or value is wrong!
 #endif
 #define CO_RX_CNT_HB_CONS OD_CNT_ARR_1016
#else
 #define CO_RX_CNT_HB_CONS 0
#endif

#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
 #define CO_RX_CNT_NG_SLV 1
 #define CO_TX_CNT_NG_SLV 1
#else
 #define CO_RX_CNT_NG_SLV 0
 #define CO_TX_CNT_NG_SLV 0
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
 #define CO_RX_CNT_NG_MST 1
 #define CO_TX_CNT_NG_MST 1
#else
 #define CO_RX_CNT_NG_MST 0
 #define CO_TX_CNT_NG_MST 0
#endif

#if OD_CNT_EM != 1
 #error OD_CNT_EM from OD.h not correct!
#endif
#ifndef OD_ENTRY_H1003
 #define OD_ENTRY_H1003 NULL
#endif
#ifndef OD_CNT_ARR_1003
 #define OD_CNT_ARR_1003 8
#endif
#if (CO_CONFIG_EM) & CO_CONFIG_EM_PRODUCER
 #if OD_CNT_EM_PROD == 1
  #define CO_TX_CNT_EM_PROD OD_CNT_EM_PROD
 #else
  #error wrong OD_CNT_EM_PROD
 #endif
 #ifndef OD_ENTRY_H1015
  #define OD_ENTRY_H1015 NULL
 #endif
#else
 #define CO_TX_CNT_EM_PROD 0
#endif
#if (CO_CONFIG_EM) & CO_CONFIG_EM_CONSUMER
 #define CO_RX_CNT_EM_CONS 1
#else
 #define CO_RX_CNT_EM_CONS 0
#endif

#if !defined OD_CNT_SDO_SRV
 #define OD_CNT_SDO_SRV 1
 #define OD_ENTRY_H1200 NULL
#elif OD_CNT_SDO_SRV < 1 || OD_CNT_SDO_SRV > 128
 #error OD_CNT_SDO_SRV from OD.h not correct!
#endif
#define CO_RX_CNT_SDO_SRV OD_CNT_SDO_SRV
#define CO_TX_CNT_SDO_SRV OD_CNT_SDO_SRV

#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
 #if !defined OD_CNT_SDO_CLI
  #define OD_CNT_SDO_CLI 0
  #define OD_ENTRY_H1280 NULL
 #elif OD_CNT_SDO_CLI < 0 || OD_CNT_SDO_CLI > 128
  #error OD_CNT_SDO_CLI from OD.h not correct!
 #endif
 #define CO_RX_CNT_SDO_CLI OD_CNT_SDO_CLI
 #define CO_TX_CNT_SDO_CLI OD_CNT_SDO_CLI
#else
 #define CO_RX_CNT_SDO_CLI 0
 #define CO_TX_CNT_SDO_CLI 0
#endif

#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
 #if !defined OD_CNT_TIME
  #define OD_CNT_TIME 0
  #define OD_ENTRY_H1012 NULL
 #elif OD_CNT_TIME < 0 || OD_CNT_TIME > 1
  #error OD_CNT_TIME from OD.h not correct!
 #endif
 #define CO_RX_CNT_TIME OD_CNT_TIME
 #if (CO_CONFIG_TIME) & CO_CONFIG_TIME_PRODUCER
  #define CO_TX_CNT_TIME OD_CNT_TIME
 #else
  #define CO_TX_CNT_TIME 0
 #endif
#else
 #define CO_RX_CNT_TIME 0
 #define CO_TX_CNT_TIME 0
#endif

#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
 #if !defined OD_CNT_SYNC
  #define OD_CNT_SYNC 0
  #define OD_ENTRY_H1005 NULL
  #define OD_ENTRY_H1006 NULL
 #elif OD_CNT_SYNC < 0 || OD_CNT_SYNC > 1
  #error OD_CNT_SYNC from OD.h not correct!
 #endif
 #define CO_RX_CNT_SYNC OD_CNT_SYNC
 #if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_PRODUCER
  #define CO_TX_CNT_SYNC OD_CNT_SYNC
 #else
  #define CO_TX_CNT_SYNC 0
 #endif
 #ifndef OD_ENTRY_H1007
  #define OD_ENTRY_H1007 NULL
 #endif
 #ifndef OD_ENTRY_H1019
  #define OD_ENTRY_H1019 NULL
 #endif
#else
 #define CO_RX_CNT_SYNC 0
 #define CO_TX_CNT_SYNC 0
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
 #if !defined OD_CNT_RPDO
  #define OD_CNT_RPDO 0
  #define OD_ENTRY_H1400 NULL
  #define OD_ENTRY_H1600 NULL
 #elif OD_CNT_RPDO < 0 || OD_CNT_RPDO > 0x200
  #error OD_CNT_RPDO from OD.h not correct!
 #endif
 #define CO_RX_CNT_RPDO OD_CNT_RPDO
#else
 #define CO_RX_CNT_RPDO 0
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
 #if !defined OD_CNT_TPDO
  #define OD_CNT_TPDO 0
  #define OD_ENTRY_H1800 NULL
  #define OD_ENTRY_H1A00 NULL
 #elif OD_CNT_TPDO < 0 || OD_CNT_TPDO > 0x200
  #error OD_CNT_TPDO from OD.h not correct!
 #endif
 #define CO_TX_CNT_TPDO OD_CNT_TPDO
#else
 #define CO_TX_CNT_TPDO 0
#endif

#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
 #define OD_CNT_LEDS 1
#endif

#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
 #if !defined OD_CNT_GFC
  #define OD_CNT_GFC 0
  #define OD_ENTRY_H1300 NULL
 #elif OD_CNT_GFC < 0 || OD_CNT_GFC > 1
  #error OD_CNT_GFC from OD.h not correct!
 #endif
 #define CO_RX_CNT_GFC OD_CNT_GFC
 #define CO_TX_CNT_GFC OD_CNT_GFC
#else
 #define CO_RX_CNT_GFC 0
 #define CO_TX_CNT_GFC 0
#endif

#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
 #if !defined OD_CNT_SRDO
  #define OD_CNT_SRDO 0
  #define OD_ENTRY_H1301 NULL
  #define OD_ENTRY_H1381 NULL
  #define OD_ENTRY_H13FE NULL
  #define OD_ENTRY_H13FF NULL
 #elif OD_CNT_SRDO < 0 || OD_CNT_SRDO > 64
  #error OD_CNT_SRDO from OD.h not correct!
 #endif
 #define CO_RX_CNT_SRDO OD_CNT_SRDO
 #define CO_TX_CNT_SRDO OD_CNT_SRDO
#else
 #define CO_RX_CNT_SRDO 0
 #define CO_TX_CNT_SRDO 0
#endif

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
 #define OD_CNT_LSS_SLV 1
#else
 #define OD_CNT_LSS_SLV 0
#endif
#define CO_RX_CNT_LSS_SLV OD_CNT_LSS_SLV
#define CO_TX_CNT_LSS_SLV OD_CNT_LSS_SLV

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
 #define OD_CNT_LSS_MST 1
#else
 #define OD_CNT_LSS_MST 0
#endif
#define CO_RX_CNT_LSS_MST OD_CNT_LSS_MST
#define CO_TX_CNT_LSS_MST OD_CNT_LSS_MST

#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
 #define OD_CNT_GTWA 1
#endif

#if (CO_CONFIG_TRACE) & CO_CONFIG_TRACE_ENABLE
 #if !defined OD_CNT_TRACE
  #define OD_CNT_TRACE 0
 #elif OD_CNT_TRACE < 0
  #error OD_CNT_TRACE from OD.h not correct!
 #endif
#endif

/* Indexes of CO_CANrx_t and CO_CANtx_t objects in CO_CANmodule_t and total
 * number of them. Indexes are sorted in a way, that objects with highest
 * priority of the CAN identifier are listed first. */
#define CO_RX_IDX_NMT_SLV   0
#define CO_RX_IDX_SYNC      (CO_RX_IDX_NMT_SLV  + CO_RX_CNT_NMT_SLV)
#define CO_RX_IDX_EM_CONS   (CO_RX_IDX_SYNC     + CO_RX_CNT_SYNC)
#define CO_RX_IDX_TIME      (CO_RX_IDX_EM_CONS  + CO_RX_CNT_EM_CONS)
#define CO_RX_IDX_GFC       (CO_RX_IDX_TIME     + CO_RX_CNT_TIME)
#define CO_RX_IDX_SRDO      (CO_RX_IDX_GFC      + CO_RX_CNT_GFC)
#define CO_RX_IDX_RPDO      (CO_RX_IDX_SRDO     + CO_RX_CNT_SRDO * 2)
#define CO_RX_IDX_SDO_SRV   (CO_RX_IDX_RPDO     + CO_RX_CNT_RPDO)
#define CO_RX_IDX_SDO_CLI   (CO_RX_IDX_SDO_SRV  + CO_RX_CNT_SDO_SRV)
#define CO_RX_IDX_HB_CONS   (CO_RX_IDX_SDO_CLI  + CO_RX_CNT_SDO_CLI)
#define CO_RX_IDX_NG_SLV    (CO_RX_IDX_HB_CONS  + CO_RX_CNT_HB_CONS)
#define CO_RX_IDX_NG_MST    (CO_RX_IDX_NG_SLV   + CO_RX_CNT_NG_SLV)
#define CO_RX_IDX_LSS_SLV   (CO_RX_IDX_NG_MST   + CO_RX_CNT_NG_MST)
#define CO_RX_IDX_LSS_MST   (CO_RX_IDX_LSS_SLV  + CO_RX_CNT_LSS_SLV)
#define CO_CNT_ALL_RX_MSGS  (CO_RX_IDX_LSS_MST  + CO_RX_CNT_LSS_MST)

#define CO_TX_IDX_NMT_MST   0
#define CO_TX_IDX_SYNC      (CO_TX_IDX_NMT_MST  + CO_TX_CNT_NMT_MST)
#define CO_TX_IDX_EM_PROD   (CO_TX_IDX_SYNC     + CO_TX_CNT_SYNC)
#define CO_TX_IDX_TIME      (CO_TX_IDX_EM_PROD  + CO_TX_CNT_EM_PROD)
#define CO_TX_IDX_GFC       (CO_TX_IDX_TIME     + CO_TX_CNT_TIME)
#define CO_TX_IDX_SRDO      (CO_TX_IDX_GFC      + CO_TX_CNT_GFC)
#define CO_TX_IDX_TPDO      (CO_TX_IDX_SRDO     + CO_TX_CNT_SRDO * 2)
#define CO_TX_IDX_SDO_SRV   (CO_TX_IDX_TPDO     + CO_TX_CNT_TPDO)
#define CO_TX_IDX_SDO_CLI   (CO_TX_IDX_SDO_SRV  + CO_TX_CNT_SDO_SRV)
#define CO_TX_IDX_HB_PROD   (CO_TX_IDX_SDO_CLI  + CO_TX_CNT_SDO_CLI)
#define CO_TX_IDX_NG_SLV    (CO_TX_IDX_HB_PROD  + CO_TX_CNT_HB_PROD)
#define CO_TX_IDX_NG_MST    (CO_TX_IDX_NG_SLV   + CO_TX_CNT_NG_SLV)
#define CO_TX_IDX_LSS_SLV   (CO_TX_IDX_NG_MST   + CO_TX_CNT_NG_MST)
#define CO_TX_IDX_LSS_MST   (CO_TX_IDX_LSS_SLV  + CO_TX_CNT_LSS_SLV)
#define CO_CNT_ALL_TX_MSGS  (CO_TX_IDX_LSS_MST  + CO_TX_CNT_LSS_MST)
#endif /* #ifdef #else CO_MULTIPLE_OD */


/* Objects from heap **********************************************************/
#ifndef CO_USE_GLOBALS
#include <stdlib.h>

/* Default allocation strategy ************************************************/
#if !defined(CO_alloc) || !defined(CO_free)
#if defined(CO_alloc)
#warning CO_alloc is defined but CO_free is not. using default values instead
#undef CO_alloc
#endif
#if defined(CO_free)
#warning CO_free is defined but CO_alloc is not. using default values instead
#undef CO_free
#endif

/*
 * Allocate memory for number of elements, each of specific size
 * Allocated memory must be reset to all zeros
 */
#define CO_alloc(num, size)             calloc((num), (size))
#define CO_free(ptr)                    free((ptr))

#endif

/* Define macros for allocation */
#define CO_alloc_break_on_fail(var, num, size)   if (((var) = CO_alloc((num), (size))) != NULL) { mem += (size) * (num); } else { break; }

#ifdef CO_MULTIPLE_OD
#define ON_MULTI_OD(sentence) sentence
#else
#define ON_MULTI_OD(sentence)
#endif

CO_t *CO_new(CO_config_t *config, uint32_t *heapMemoryUsed) {
    CO_t *co = NULL;
    /* return values */
    CO_t *coFinal = NULL;
    uint32_t mem = 0;

    /* For each object:
     * - allocate memory, verify allocation and calculate size of heap used
     * - if CO_MULTIPLE_OD is defined:
     *   - use config structure
     *   - calculate number of CANrx and CYNtx messages: RX_CNT_xx and TX_CNT_xx
     *   - calculate indexes: RX_IDX_xx and TX_IDX_xx
     *   - calculate total count of CAN message buffers: CNT_ALL_RX_MSGS and
     *     CNT_ALL_TX_MSGS. */

    do {
#ifdef CO_MULTIPLE_OD
        /* verify arguments */
        if (config == NULL || config->CNT_NMT > 1 || config->CNT_HB_CONS > 1
            || config->CNT_EM > 1 || config->CNT_SDO_SRV > 128
            || config->CNT_SDO_CLI > 128 || config->CNT_SYNC > 1
            || config->CNT_RPDO > 512 || config->CNT_TPDO > 512
            || config->CNT_TIME > 1 || config->CNT_LEDS > 1
            || config->CNT_GFC > 1 || config->CNT_SRDO > 64
            || config->CNT_LSS_SLV > 1 || config->CNT_LSS_MST > 1
            || config->CNT_GTWA > 1
        ) {
            break;
        }
#else
        (void) config;
#endif

        /* CANopen object */
        CO_alloc_break_on_fail(co, 1, sizeof(*co));

#ifdef CO_MULTIPLE_OD
        co->config = config;
#endif

        /* NMT_Heartbeat */
        ON_MULTI_OD(uint8_t RX_CNT_NMT_SLV = 0);
        ON_MULTI_OD(uint8_t TX_CNT_NMT_MST = 0);
        ON_MULTI_OD(uint8_t TX_CNT_HB_PROD = 0);
        if (CO_GET_CNT(NMT) == 1) {
            CO_alloc_break_on_fail(co->NMT, CO_GET_CNT(NMT), sizeof(*co->NMT));
            ON_MULTI_OD(RX_CNT_NMT_SLV = 1);
 #if (CO_CONFIG_NMT) & CO_CONFIG_NMT_MASTER
            ON_MULTI_OD(TX_CNT_NMT_MST = 1);
 #endif
            ON_MULTI_OD(TX_CNT_HB_PROD = 1);
        }

#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
        ON_MULTI_OD(uint8_t RX_CNT_HB_CONS = 0);
        if (CO_GET_CNT(HB_CONS) == 1) {
            uint8_t countOfMonitoredNodes = CO_GET_CNT(ARR_1016);
            CO_alloc_break_on_fail(co->HBcons, CO_GET_CNT(HB_CONS), sizeof(*co->HBcons));
            CO_alloc_break_on_fail(co->HBconsMonitoredNodes, countOfMonitoredNodes, sizeof(*co->HBconsMonitoredNodes));
            ON_MULTI_OD(RX_CNT_HB_CONS = countOfMonitoredNodes);
        }
#endif

        /* Node guarding */
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
        CO_alloc_break_on_fail(co->NGslave, 1, sizeof(*co->NGslave));
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
        CO_alloc_break_on_fail(co->NGmaster, 1, sizeof(*co->NGmaster));
#endif

        /* Emergency */
        ON_MULTI_OD(uint8_t RX_CNT_EM_CONS = 0);
        ON_MULTI_OD(uint8_t TX_CNT_EM_PROD = 0);
        if (CO_GET_CNT(EM) == 1) {
            CO_alloc_break_on_fail(co->em, CO_GET_CNT(EM), sizeof(*co->em));
 #if (CO_CONFIG_EM) & CO_CONFIG_EM_CONSUMER
            ON_MULTI_OD(RX_CNT_EM_CONS = 1);
 #endif
 #if (CO_CONFIG_EM) & CO_CONFIG_EM_PRODUCER
            ON_MULTI_OD(TX_CNT_EM_PROD = 1);
 #endif
 #if (CO_CONFIG_EM) & (CO_CONFIG_EM_PRODUCER | CO_CONFIG_EM_HISTORY)
            uint8_t fifoSize = CO_GET_CNT(ARR_1003) + 1;
            if (fifoSize >= 2) {
                CO_alloc_break_on_fail(co->em_fifo, fifoSize, sizeof(*co->em_fifo));
            }
 #endif
        }

        /* SDOserver */
        ON_MULTI_OD(uint8_t RX_CNT_SDO_SRV = 0);
        ON_MULTI_OD(uint8_t TX_CNT_SDO_SRV = 0);
        if (CO_GET_CNT(SDO_SRV) > 0) {
            CO_alloc_break_on_fail(co->SDOserver, CO_GET_CNT(SDO_SRV), sizeof(*co->SDOserver));
            ON_MULTI_OD(RX_CNT_SDO_SRV = config->CNT_SDO_SRV);
            ON_MULTI_OD(TX_CNT_SDO_SRV = config->CNT_SDO_SRV);
        }

#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
        ON_MULTI_OD(uint8_t RX_CNT_SDO_CLI = 0);
        ON_MULTI_OD(uint8_t TX_CNT_SDO_CLI = 0);
        if (CO_GET_CNT(SDO_CLI) > 0) {
            CO_alloc_break_on_fail(co->SDOclient, CO_GET_CNT(SDO_CLI), sizeof(*co->SDOclient));
            ON_MULTI_OD(RX_CNT_SDO_CLI = config->CNT_SDO_CLI);
            ON_MULTI_OD(TX_CNT_SDO_CLI = config->CNT_SDO_CLI);
        }
#endif

#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
        ON_MULTI_OD(uint8_t RX_CNT_TIME = 0);
        ON_MULTI_OD(uint8_t TX_CNT_TIME = 0);
        if (CO_GET_CNT(TIME) == 1) {
            CO_alloc_break_on_fail(co->TIME, CO_GET_CNT(TIME), sizeof(*co->TIME));
            ON_MULTI_OD(RX_CNT_TIME = 1);
 #if (CO_CONFIG_TIME) & CO_CONFIG_TIME_PRODUCER
            ON_MULTI_OD(TX_CNT_TIME = 1);
 #endif
        }
#endif

#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
        ON_MULTI_OD(uint8_t RX_CNT_SYNC = 0);
        ON_MULTI_OD(uint8_t TX_CNT_SYNC = 0);
        if (CO_GET_CNT(SYNC) == 1) {
            CO_alloc_break_on_fail(co->SYNC, CO_GET_CNT(SYNC), sizeof(*co->SYNC));
            ON_MULTI_OD(RX_CNT_SYNC = 1);
 #if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_PRODUCER
            ON_MULTI_OD(TX_CNT_SYNC = 1);
 #endif
        }
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
        ON_MULTI_OD(uint16_t RX_CNT_RPDO = 0);
        if (CO_GET_CNT(RPDO) > 0) {
            CO_alloc_break_on_fail(co->RPDO, CO_GET_CNT(RPDO), sizeof(*co->RPDO));
            ON_MULTI_OD(RX_CNT_RPDO = config->CNT_RPDO);
        }
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
        ON_MULTI_OD(uint16_t TX_CNT_TPDO = 0);
        if (CO_GET_CNT(TPDO) > 0) {
            CO_alloc_break_on_fail(co->TPDO, CO_GET_CNT(TPDO), sizeof(*co->TPDO));
            ON_MULTI_OD(TX_CNT_TPDO = config->CNT_TPDO);
        }
#endif

#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
        if (CO_GET_CNT(LEDS) == 1) {
            CO_alloc_break_on_fail(co->LEDs, CO_GET_CNT(LEDS), sizeof(*co->LEDs));
        }
#endif

#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
        ON_MULTI_OD(uint8_t RX_CNT_GFC = 0);
        ON_MULTI_OD(uint8_t TX_CNT_GFC = 0);
        if (CO_GET_CNT(GFC) == 1) {
            CO_alloc_break_on_fail(co->GFC, CO_GET_CNT(GFC), sizeof(*co->GFC));
            ON_MULTI_OD(RX_CNT_GFC = 1);
            ON_MULTI_OD(TX_CNT_GFC = 1);
        }
#endif

#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
        ON_MULTI_OD(uint8_t RX_CNT_SRDO = 0);
        ON_MULTI_OD(uint8_t TX_CNT_SRDO = 0);
        if (CO_GET_CNT(SRDO) > 0) {
            CO_alloc_break_on_fail(co->SRDOGuard, 1, sizeof(*co->SRDOGuard));
            CO_alloc_break_on_fail(co->SRDO, CO_GET_CNT(SRDO), sizeof(*co->SRDO));
            ON_MULTI_OD(RX_CNT_SRDO = config->CNT_SRDO * 2);
            ON_MULTI_OD(TX_CNT_SRDO = config->CNT_SRDO * 2);
        }
#endif

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
        ON_MULTI_OD(uint8_t RX_CNT_LSS_SLV = 0);
        ON_MULTI_OD(uint8_t TX_CNT_LSS_SLV = 0);
        if (CO_GET_CNT(LSS_SLV) == 1) {
            CO_alloc_break_on_fail(co->LSSslave, CO_GET_CNT(LSS_SLV), sizeof(*co->LSSslave));
            ON_MULTI_OD(RX_CNT_LSS_SLV = 1);
            ON_MULTI_OD(TX_CNT_LSS_SLV = 1);
        }
#endif

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
        ON_MULTI_OD(uint8_t RX_CNT_LSS_MST = 0);
        ON_MULTI_OD(uint8_t TX_CNT_LSS_MST = 0);
        if (CO_GET_CNT(LSS_MST) == 1) {
            CO_alloc_break_on_fail(co->LSSmaster, CO_GET_CNT(LSS_MST), sizeof(*co->LSSmaster));
            ON_MULTI_OD(RX_CNT_LSS_MST = 1);
            ON_MULTI_OD(TX_CNT_LSS_MST = 1);
        }
#endif

#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
        if (CO_GET_CNT(GTWA) == 1) {
            CO_alloc_break_on_fail(co->gtwa, CO_GET_CNT(GTWA), sizeof(*co->gtwa));
        }
#endif

#if (CO_CONFIG_TRACE) & CO_CONFIG_TRACE_ENABLE
        if (CO_GET_CNT(TRACE) > 0) {
            CO_alloc_break_on_fail(co->trace, CO_GET_CNT(TRACE), sizeof(*co->trace));
        }
#endif

#ifdef CO_MULTIPLE_OD
        /* Indexes of CO_CANrx_t and CO_CANtx_t objects in CO_CANmodule_t and
         * total number of them. Indexes are sorted in a way, that objects with
         * highest priority of the CAN identifier are listed first. */
        int16_t idxRx = 0;
        co->RX_IDX_NMT_SLV = idxRx; idxRx += RX_CNT_NMT_SLV;
#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
        co->RX_IDX_SYNC = idxRx; idxRx += RX_CNT_SYNC;
#endif
        co->RX_IDX_EM_CONS = idxRx; idxRx += RX_CNT_EM_CONS;
#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
        co->RX_IDX_TIME = idxRx; idxRx += RX_CNT_TIME;
#endif
#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
        co->RX_IDX_GFC = idxRx; idxRx += RX_CNT_GFC;
#endif
#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
        co->RX_IDX_SRDO = idxRx; idxRx += RX_CNT_SRDO * 2;
#endif
#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
        co->RX_IDX_RPDO = idxRx; idxRx += RX_CNT_RPDO;
#endif
        co->RX_IDX_SDO_SRV = idxRx; idxRx += RX_CNT_SDO_SRV;
#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
        co->RX_IDX_SDO_CLI = idxRx; idxRx += RX_CNT_SDO_CLI;
#endif
#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
        co->RX_IDX_HB_CONS = idxRx; idxRx += RX_CNT_HB_CONS;
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
        co->RX_IDX_NG_SLV = idxRx; idxRx += 1;
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
        co->RX_IDX_NG_MST = idxRx; idxRx += 1;
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
        co->RX_IDX_LSS_SLV = idxRx; idxRx += RX_CNT_LSS_SLV;
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
        co->RX_IDX_LSS_MST = idxRx; idxRx += RX_CNT_LSS_MST;
#endif
        co->CNT_ALL_RX_MSGS = idxRx;

        int16_t idxTx = 0;
        co->TX_IDX_NMT_MST = idxTx; idxTx += TX_CNT_NMT_MST;
#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
        co->TX_IDX_SYNC = idxTx; idxTx += TX_CNT_SYNC;
#endif
        co->TX_IDX_EM_PROD = idxTx; idxTx += TX_CNT_EM_PROD;
#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
        co->TX_IDX_TIME = idxTx; idxTx += TX_CNT_TIME;
#endif
#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
        co->TX_IDX_GFC = idxTx; idxTx += TX_CNT_GFC;
#endif
#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
        co->TX_IDX_SRDO = idxTx; idxTx += TX_CNT_SRDO * 2;
#endif
#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
        co->TX_IDX_TPDO = idxTx; idxTx += TX_CNT_TPDO;
#endif
        co->TX_IDX_SDO_SRV = idxTx; idxTx += TX_CNT_SDO_SRV;
#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
        co->TX_IDX_SDO_CLI = idxTx; idxTx += TX_CNT_SDO_CLI;
#endif
        co->TX_IDX_HB_PROD = idxTx; idxTx += TX_CNT_HB_PROD;
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
        co->TX_IDX_NG_SLV = idxTx; idxTx += 1;
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
        co->TX_IDX_NG_MST = idxTx; idxTx += 1;
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
        co->TX_IDX_LSS_SLV = idxTx; idxTx += TX_CNT_LSS_SLV;
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
        co->TX_IDX_LSS_MST = idxTx; idxTx += TX_CNT_LSS_MST;
#endif
        co->CNT_ALL_TX_MSGS = idxTx;
#endif /* #ifdef CO_MULTIPLE_OD */

        /* CANmodule */
        CO_alloc_break_on_fail(co->CANmodule, 1, sizeof(*co->CANmodule));

        /* CAN RX blocks */
        CO_alloc_break_on_fail(co->CANrx, CO_GET_CO(CNT_ALL_RX_MSGS), sizeof(*co->CANrx));

        /* CAN TX blocks */
        CO_alloc_break_on_fail(co->CANtx, CO_GET_CO(CNT_ALL_TX_MSGS), sizeof(*co->CANtx));

        /* finish successfully, set other parameters */
        co->nodeIdUnconfigured = true;
        coFinal = co;
    } while (false);

    if (coFinal == NULL) {
        CO_delete(co);
    }
    if (heapMemoryUsed != NULL) {
        *heapMemoryUsed = mem;
    }
    return coFinal;
}

void CO_delete(CO_t *co) {
    if (co == NULL) {
        return;
    }

    CO_CANmodule_disable(co->CANmodule);

    /* CANmodule */
    CO_free(co->CANtx);
    CO_free(co->CANrx);
    CO_free(co->CANmodule);

#if (CO_CONFIG_TRACE) & CO_CONFIG_TRACE_ENABLE
    CO_free(co->trace);
#endif

#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
    CO_free(co->gtwa);
#endif

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
    CO_free(co->LSSmaster);
#endif

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    CO_free(co->LSSslave);
#endif

#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
    CO_free(co->SRDO);
    CO_free(co->SRDOGuard);
#endif

#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
    CO_free(co->GFC);
#endif

#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
    CO_free(co->LEDs);
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
    CO_free(co->TPDO);
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
    CO_free(co->RPDO);
#endif

#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
    CO_free(co->SYNC);
#endif

#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
    CO_free(co->TIME);
#endif

#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
    free(co->SDOclient);
#endif

    /* SDOserver */
    CO_free(co->SDOserver);

    /* Emergency */
    CO_free(co->em);
#if (CO_CONFIG_EM) & (CO_CONFIG_EM_PRODUCER | CO_CONFIG_EM_HISTORY)
    CO_free(co->em_fifo);
#endif

#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
    CO_free(co->NGslave);
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
    CO_free(co->NGmaster);
#endif

#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
    CO_free(co->HBconsMonitoredNodes);
    CO_free(co->HBcons);
#endif

    /* NMT_Heartbeat */
    CO_free(co->NMT);

    /* CANopen object */
    CO_free(co);
}
#endif /* #ifndef CO_USE_GLOBALS */


/* Objects as globals *********************************************************/
#ifdef CO_USE_GLOBALS
 #ifdef CO_MULTIPLE_OD
  #error CO_MULTIPLE_OD can not be used with CO_USE_GLOBALS
 #endif
    static CO_t COO;
    static CO_CANmodule_t COO_CANmodule;
    static CO_CANrx_t COO_CANmodule_rxArray[CO_CNT_ALL_RX_MSGS];
    static CO_CANtx_t COO_CANmodule_txArray[CO_CNT_ALL_TX_MSGS];
    static CO_NMT_t COO_NMT;
#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
    static CO_HBconsumer_t COO_HBcons;
    static CO_HBconsNode_t COO_HBconsMonitoredNodes[OD_CNT_ARR_1016];
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
    static CO_nodeGuardingSlave_t COO_NGslave;
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
    static CO_nodeGuardingMaster_t COO_NGmaster;
#endif
    static CO_EM_t COO_EM;
#if (CO_CONFIG_EM) & (CO_CONFIG_EM_PRODUCER | CO_CONFIG_EM_HISTORY)
    static CO_EM_fifo_t COO_EM_FIFO[CO_GET_CNT(ARR_1003) + 1];
#endif
    static CO_SDOserver_t COO_SDOserver[OD_CNT_SDO_SRV];
#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
    static CO_SDOclient_t COO_SDOclient[OD_CNT_SDO_CLI];
#endif
#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
    static CO_TIME_t COO_TIME;
#endif
#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
    static CO_SYNC_t COO_SYNC;
#endif
#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
    static CO_RPDO_t COO_RPDO[OD_CNT_RPDO];
#endif
#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
    static CO_TPDO_t COO_TPDO[OD_CNT_TPDO];
#endif
#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
    static CO_LEDs_t COO_LEDs;
#endif
#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
    static CO_GFC_t COO_GFC;
#endif
#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
    static CO_SRDOGuard_t COO_SRDOGuard;
    static CO_SRDO_t COO_SRDO[OD_CNT_SRDO];
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    static CO_LSSslave_t COO_LSSslave;
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
    static CO_LSSmaster_t COO_LSSmaster;
#endif
#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
    static CO_GTWA_t COO_gtwa;
#endif
#if (CO_CONFIG_TRACE) & CO_CONFIG_TRACE_ENABLE
  #ifndef CO_TRACE_BUFFER_SIZE_FIXED
    #define CO_TRACE_BUFFER_SIZE_FIXED 100
  #endif
    static CO_trace_t COO_trace[OD_CNT_TRACE];
    static uint32_t COO_traceTimeBuffers[OD_CNT_TRACE][CO_TRACE_BUFFER_SIZE_FIXED];
    static int32_t COO_traceValueBuffers[OD_CNT_TRACE][CO_TRACE_BUFFER_SIZE_FIXED];
#endif

CO_t *CO_new(CO_config_t *config, uint32_t *heapMemoryUsed) {
    (void)config; (void)heapMemoryUsed;

    CO_t *co = &COO;

    co->CANmodule = &COO_CANmodule;
    co->CANrx = &COO_CANmodule_rxArray[0];
    co->CANtx = &COO_CANmodule_txArray[0];

    co->NMT = &COO_NMT;
#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
    co->HBcons = &COO_HBcons;
    co->HBconsMonitoredNodes = &COO_HBconsMonitoredNodes[0];
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
    co->NGslave = &COO_NGslave;
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
    co->NGmaster = &COO_NGmaster;
#endif
    co->em = &COO_EM;
#if (CO_CONFIG_EM) & (CO_CONFIG_EM_PRODUCER | CO_CONFIG_EM_HISTORY)
    co->em_fifo = &COO_EM_FIFO[0];
#endif
    co->SDOserver = &COO_SDOserver[0];
#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
    co->SDOclient = &COO_SDOclient[0];
#endif
#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
    co->TIME = &COO_TIME;
#endif
#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
    co->SYNC = &COO_SYNC;
#endif
#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
    co->RPDO = &COO_RPDO[0];
#endif
#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
    co->TPDO = &COO_TPDO[0];
#endif
#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
    co->LEDs = &COO_LEDs;
#endif
#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
    co->GFC = &COO_GFC;
#endif
#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
    co->SRDOGuard = &COO_SRDOGuard;
    co->SRDO = &COO_SRDO[0];
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    co->LSSslave = &COO_LSSslave;
#endif
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
    co->LSSmaster = &COO_LSSmaster;
#endif
#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
    co->gtwa = &COO_gtwa;
#endif
#if (CO_CONFIG_TRACE) & CO_CONFIG_TRACE_ENABLE
    co->trace = &COO_trace[0];
    co->traceTimeBuffers = &COO_traceTimeBuffers[0][0];
    co->traceValueBuffers = &COO_traceValueBuffers[0][0];
    co->traceBufferSize = CO_TRACE_BUFFER_SIZE_FIXED;
#endif

    return co;
}

void CO_delete(CO_t *co) {
    if (co == NULL) {
        return;
    }

    CO_CANmodule_disable(co->CANmodule);
}
#endif /* #ifdef CO_USE_GLOBALS */

/* Helper functions ***********************************************************/
bool_t CO_isLSSslaveEnabled(CO_t *co) {
    (void) co; /* may be unused */
    bool_t en = false;
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    if (CO_GET_CNT(LSS_SLV) == 1) en = true;
#endif
    return en;
}

/******************************************************************************/
CO_ReturnError_t CO_CANinit(CO_t *co, void *CANptr, uint16_t bitRate) {
    CO_ReturnError_t err;

    if (co == NULL) return CO_ERROR_ILLEGAL_ARGUMENT;

    co->CANmodule->CANnormal = false;
    CO_CANsetConfigurationMode(CANptr);

    /* CANmodule */
    err = CO_CANmodule_init(co->CANmodule,
                            CANptr,
                            co->CANrx,
                            CO_GET_CO(CNT_ALL_RX_MSGS),
                            co->CANtx,
                            CO_GET_CO(CNT_ALL_TX_MSGS),
                            bitRate);

    return err;
}


/******************************************************************************/
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
CO_ReturnError_t CO_LSSinit(CO_t *co,
                            CO_LSS_address_t *lssAddress,
                            uint8_t *pendingNodeID,
                            uint16_t *pendingBitRate)
{
    CO_ReturnError_t err;

    if (co == NULL || CO_GET_CNT(LSS_SLV) != 1) {
        return CO_ERROR_ILLEGAL_ARGUMENT;
    }

    /* LSSslave */
    err = CO_LSSslave_init(co->LSSslave,
                           lssAddress,
                           pendingBitRate,
                           pendingNodeID,
                           co->CANmodule,
                           CO_GET_CO(RX_IDX_LSS_SLV),
                           CO_CAN_ID_LSS_MST,
                           co->CANmodule,
                           CO_GET_CO(TX_IDX_LSS_SLV),
                           CO_CAN_ID_LSS_SLV);

    return err;
}
#endif /* (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE */


/******************************************************************************/
CO_ReturnError_t CO_CANopenInit(CO_t *co,
                                CO_NMT_t *NMT,
                                CO_EM_t *em,
                                OD_t *od,
                                OD_entry_t *OD_statusBits,
                                CO_NMT_control_t NMTcontrol,
                                uint16_t firstHBTime_ms,
                                uint16_t SDOserverTimeoutTime_ms,
                                uint16_t SDOclientTimeoutTime_ms,
                                bool_t SDOclientBlockTransfer,
                                uint8_t nodeId,
                                uint32_t *errInfo)
{
    (void)SDOclientTimeoutTime_ms; (void)SDOclientBlockTransfer;
    CO_ReturnError_t err;

    if (co == NULL
        || (CO_GET_CNT(NMT) == 0 && NMT == NULL)
        || (CO_GET_CNT(EM) == 0 && em == NULL)
    ) {
        return CO_ERROR_ILLEGAL_ARGUMENT;
    }

    /* alternatives */
    if (CO_GET_CNT(NMT) == 0) {
        co->NMT = NMT;
    }
    if (em == NULL) {
        em = co->em;
    }

    /* Verify CANopen Node-ID */
    co->nodeIdUnconfigured = false;
#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    if (CO_GET_CNT(LSS_SLV) == 1 && nodeId == CO_LSS_NODE_ID_ASSIGNMENT) {
        co->nodeIdUnconfigured = true;
    }
    else
#endif
    if (nodeId < 1 || nodeId > 127) {
        return CO_ERROR_ILLEGAL_ARGUMENT;
    }

#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
    if (CO_GET_CNT(LEDS) == 1) {
        err = CO_LEDs_init(co->LEDs);
        if (err) return err;
    }
#endif

    /* CANopen Node ID is unconfigured, stop initialization here */
    if (co->nodeIdUnconfigured) {
        return CO_ERROR_NODE_ID_UNCONFIGURED_LSS;
    }

    /* Emergency */
    if (CO_GET_CNT(EM) == 1) {
        err = CO_EM_init(co->em,
                         co->CANmodule,
                         OD_GET(H1001, OD_H1001_ERR_REG),
 #if (CO_CONFIG_EM) & (CO_CONFIG_EM_PRODUCER | CO_CONFIG_EM_HISTORY)
                         co->em_fifo,
                         (CO_GET_CNT(ARR_1003) + 1),
 #endif
 #if (CO_CONFIG_EM) & CO_CONFIG_EM_PRODUCER
                         OD_GET(H1014, OD_H1014_COBID_EMERGENCY),
                         CO_GET_CO(TX_IDX_EM_PROD),
  #if (CO_CONFIG_EM) & CO_CONFIG_EM_PROD_INHIBIT
                         OD_GET(H1015, OD_H1015_INHIBIT_TIME_EMCY),
  #endif
 #endif
 #if (CO_CONFIG_EM) & CO_CONFIG_EM_HISTORY
                         OD_GET(H1003, OD_H1003_PREDEF_ERR_FIELD),
 #endif
 #if (CO_CONFIG_EM) & CO_CONFIG_EM_STATUS_BITS
                         OD_statusBits,
 #endif
 #if (CO_CONFIG_EM) & CO_CONFIG_EM_CONSUMER
                         co->CANmodule,
                         CO_GET_CO(RX_IDX_EM_CONS),
 #endif
                         nodeId,
                         errInfo);
        if (err) return err;
    }

    /* NMT_Heartbeat */
    if (CO_GET_CNT(NMT) == 1) {
        err = CO_NMT_init(co->NMT,
                          OD_GET(H1017, OD_H1017_PRODUCER_HB_TIME),
                          em,
                          nodeId,
                          NMTcontrol,
                          firstHBTime_ms,
                          co->CANmodule,
                          CO_GET_CO(RX_IDX_NMT_SLV),
                          CO_CAN_ID_NMT_SERVICE,
 #if (CO_CONFIG_NMT) & CO_CONFIG_NMT_MASTER
                          co->CANmodule,
                          CO_GET_CO(TX_IDX_NMT_MST),
                          CO_CAN_ID_NMT_SERVICE,
 #endif
                          co->CANmodule,
                          CO_GET_CO(TX_IDX_HB_PROD),
                          CO_CAN_ID_HEARTBEAT + nodeId,
                          errInfo);
        if (err) return err;
    }

#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
    if (CO_GET_CNT(HB_CONS) == 1) {
        err = CO_HBconsumer_init(co->HBcons,
                                 em,
                                 co->HBconsMonitoredNodes,
                                 CO_GET_CNT(ARR_1016),
                                 OD_GET(H1016, OD_H1016_CONSUMER_HB_TIME),
                                 co->CANmodule,
                                 CO_GET_CO(RX_IDX_HB_CONS),
                                 errInfo);
        if (err) return err;
    }
#endif

#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
    err = CO_nodeGuardingSlave_init(co->NGslave,
                                    OD_GET(H100C, OD_H100C_GUARD_TIME),
                                    OD_GET(H100D, OD_H100D_LIFETIME_FACTOR),
                                    em,
                                    CO_CAN_ID_HEARTBEAT + nodeId,
                                    co->CANmodule,
                                    CO_GET_CO(RX_IDX_NG_SLV),
                                    co->CANmodule,
                                    CO_GET_CO(TX_IDX_NG_SLV),
                                    errInfo);
    if (err) return err;
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
    err = CO_nodeGuardingMaster_init(co->NGmaster,
                                     em,
                                     co->CANmodule,
                                     CO_GET_CO(RX_IDX_NG_MST),
                                     co->CANmodule,
                                     CO_GET_CO(TX_IDX_NG_MST));
    if (err) return err;
#endif

    /* SDOserver */
    if (CO_GET_CNT(SDO_SRV) > 0) {
        OD_entry_t *SDOsrvPar = OD_GET(H1200, OD_H1200_SDO_SERVER_1_PARAM);
        for (int16_t i = 0; i < CO_GET_CNT(SDO_SRV); i++) {
            err = CO_SDOserver_init(&co->SDOserver[i],
                                    od,
                                    SDOsrvPar++,
                                    nodeId,
                                    SDOserverTimeoutTime_ms,
                                    co->CANmodule,
                                    CO_GET_CO(RX_IDX_SDO_SRV) + i,
                                    co->CANmodule,
                                    CO_GET_CO(TX_IDX_SDO_SRV) + i,
                                    errInfo);
            if (err) return err;
        }
    }

#if (CO_CONFIG_SDO_CLI) & CO_CONFIG_SDO_CLI_ENABLE
    if (CO_GET_CNT(SDO_CLI) > 0) {
        OD_entry_t *SDOcliPar = OD_GET(H1280, OD_H1280_SDO_CLIENT_1_PARAM);
        for (int16_t i = 0; i < CO_GET_CNT(SDO_CLI); i++) {
            err = CO_SDOclient_init(&co->SDOclient[i],
                                    od,
                                    SDOcliPar++,
                                    nodeId,
                                    co->CANmodule,
                                    CO_GET_CO(RX_IDX_SDO_CLI) + i,
                                    co->CANmodule,
                                    CO_GET_CO(TX_IDX_SDO_CLI) + i,
                                    errInfo);
            if (err) return err;
        }
    }
#endif

#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
    if (CO_GET_CNT(TIME) == 1) {
        err = CO_TIME_init(co->TIME,
                           OD_GET(H1012, OD_H1012_COBID_TIME),
                           co->CANmodule,
                           CO_GET_CO(RX_IDX_TIME),
#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_PRODUCER
                           co->CANmodule,
                           CO_GET_CO(TX_IDX_TIME),
#endif
                           errInfo);
        if (err) return err;
    }
#endif

#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
    if (CO_GET_CNT(SYNC) == 1) {
        err = CO_SYNC_init(co->SYNC,
                           em,
                           OD_GET(H1005, OD_H1005_COBID_SYNC),
                           OD_GET(H1006, OD_H1006_COMM_CYCL_PERIOD),
                           OD_GET(H1007, OD_H1007_SYNC_WINDOW_LEN),
                           OD_GET(H1019, OD_H1019_SYNC_CNT_OVERFLOW),
                           co->CANmodule,
                           CO_GET_CO(RX_IDX_SYNC),
#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_PRODUCER
                           co->CANmodule,
                           CO_GET_CO(TX_IDX_SYNC),
#endif
                           errInfo);
        if (err) return err;
    }
#endif

#if (CO_CONFIG_GFC) & CO_CONFIG_GFC_ENABLE
    if (CO_GET_CNT(GFC) == 1) {
        err = CO_GFC_init(co->GFC,
                          &OD_globalFailSafeCommandParameter,
                          co->CANmodule,
                          CO_GET_CO(RX_IDX_GFC),
                          CO_CAN_ID_GFC,
                          co->CANmodule,
                          CO_GET_CO(TX_IDX_GFC),
                          CO_CAN_ID_GFC);
        if (err) return err;
    }
#endif

#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
    if (CO_GET_CNT(SRDO) > 0) {
        err = CO_SRDOGuard_init(co->SRDOGuard,
                                co->SDO[0],
                                &co->NMT->operatingState,
                                &OD_configurationValid,
                                OD_H13FE_SRDO_VALID,
                                OD_H13FF_SRDO_CHECKSUM);
        if (err) return err;

        OD_entry_t *SRDOcomm = OD_GET(H1301, OD_H1301_SRDO_1_PARAM);
        OD_entry_t *SRDOmap = OD_GET(H1318, OD_H1381_SRDO_1_MAPPING);
        for (int16_t i = 0; i < CO_GET_CNT(SRDO); i++) {
            uint16_t CANdevRxIdx = CO_GET_CO(RX_IDX_SRDO) + 2 * i;
            uint16_t CANdevTxIdx = CO_GET_CO(TX_IDX_SRDO) + 2 * i;

            err = CO_SRDO_init(&co->SRDO[i],
                               co->SRDOGuard,
                               em,
                               co->SDO[0],
                               nodeId,
                               ((i == 0) ? CO_CAN_ID_SRDO_1 : 0),
                               SRDOcomm++,
                               SRDOmap++,
                               &OD_safetyConfigurationChecksum[i],
                               OD_H1301_SRDO_1_PARAM + i,
                               OD_H1381_SRDO_1_MAPPING + i,
                               co->CANmodule,
                               CANdevRxIdx,
                               CANdevRxIdx + 1,
                               co->CANmodule,
                               CANdevTxIdx,
                               CANdevTxIdx + 1);
            if (err) return err;
        }
    }
#endif

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_MASTER
    if (CO_GET_CNT(LSS_MST) == 1) {
        err = CO_LSSmaster_init(co->LSSmaster,
                                CO_LSSmaster_DEFAULT_TIMEOUT,
                                co->CANmodule,
                                CO_GET_CO(RX_IDX_LSS_MST),
                                CO_CAN_ID_LSS_SLV,
                                co->CANmodule,
                                CO_GET_CO(TX_IDX_LSS_MST),
                                CO_CAN_ID_LSS_MST);
        if (err) return err;
    }
#endif

#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
    if (CO_GET_CNT(GTWA) == 1) {
        err = CO_GTWA_init(co->gtwa,
 #if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII_SDO
                           &co->SDOclient[0],
                           SDOclientTimeoutTime_ms,
                           SDOclientBlockTransfer,
 #endif
 #if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII_NMT
                           co->NMT,
 #endif
 #if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII_LSS
                           co->LSSmaster,
 #endif
 #if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII_PRINT_LEDS
                           co->LEDs,
 #endif
                           0);
        if (err) return err;
    }
#endif

#if (CO_CONFIG_TRACE) & CO_CONFIG_TRACE_ENABLE
    if (CO_GET_CNT(TRACE) > 0) {
        for (uint16_t i = 0; i < CO_GET_CNT(TRACE); i++) {
            err = CO_trace_init(co->trace[i],
                                co->SDO[0],
                                OD_traceConfig[i].axisNo,
                                CO_traceTimeBuffers[i],
                                CO_traceValueBuffers[i],
                                CO_traceBufferSize[i],
                                &OD_traceConfig[i].map,
                                &OD_traceConfig[i].format,
                                &OD_traceConfig[i].trigger,
                                &OD_traceConfig[i].threshold,
                                &OD_trace[i].value,
                                &OD_trace[i].min,
                                &OD_trace[i].max,
                                &OD_trace[i].triggerTime,
                                OD_INDEX_TRACE_CONFIG + i,
                                OD_INDEX_TRACE + i);
            if (err) return err;
        }
    }
#endif

    return CO_ERROR_NO;
}


/******************************************************************************/
CO_ReturnError_t CO_CANopenInitPDO(CO_t *co,
                                   CO_EM_t *em,
                                   OD_t *od,
                                   uint8_t nodeId,
                                   uint32_t *errInfo)
{
    if (co == NULL) {
        return CO_ERROR_ILLEGAL_ARGUMENT;
    }
    if (nodeId < 1 || nodeId > 127 || co->nodeIdUnconfigured) {
        return (co->nodeIdUnconfigured)
               ? CO_ERROR_NODE_ID_UNCONFIGURED_LSS : CO_ERROR_ILLEGAL_ARGUMENT;
    }

#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
    if (CO_GET_CNT(RPDO) > 0) {
        OD_entry_t *RPDOcomm = OD_GET(H1400, OD_H1400_RXPDO_1_PARAM);
        OD_entry_t *RPDOmap = OD_GET(H1600, OD_H1600_RXPDO_1_MAPPING);
        for (int16_t i = 0; i < CO_GET_CNT(RPDO); i++) {
            CO_ReturnError_t err;
            uint16_t preDefinedCanId = 0;
            if (i < CO_RPDO_DEFAULT_CANID_COUNT) {
#if CO_RPDO_DEFAULT_CANID_COUNT <= 4
                preDefinedCanId = (CO_CAN_ID_RPDO_1 + i * 0x100) + nodeId;
#else
                uint16_t pdoOffset = i % 4;
                uint16_t nodeIdOffset = i / 4;
                preDefinedCanId = (CO_CAN_ID_RPDO_1 + pdoOffset * 0x100)
                                + nodeId + nodeIdOffset;
#endif
            }
            err = CO_RPDO_init(&co->RPDO[i],
                               od,
                               em,
 #if (CO_CONFIG_PDO) & CO_CONFIG_PDO_SYNC_ENABLE
                               co->SYNC,
 #endif
                               preDefinedCanId,
                               RPDOcomm++,
                               RPDOmap++,
                               co->CANmodule,
                               CO_GET_CO(RX_IDX_RPDO) + i,
                               errInfo);
            if (err) return err;
        }
    }
#endif

#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
    if (CO_GET_CNT(TPDO) > 0) {
        OD_entry_t *TPDOcomm = OD_GET(H1800, OD_H1800_TXPDO_1_PARAM);
        OD_entry_t *TPDOmap = OD_GET(H1A00, OD_H1A00_TXPDO_1_MAPPING);
        for (int16_t i = 0; i < CO_GET_CNT(TPDO); i++) {
            CO_ReturnError_t err;
            uint16_t preDefinedCanId = 0;
            if (i < CO_TPDO_DEFAULT_CANID_COUNT) {
#if CO_TPDO_DEFAULT_CANID_COUNT <= 4
                preDefinedCanId = (CO_CAN_ID_TPDO_1 + i * 0x100) + nodeId;
#else
                uint16_t pdoOffset = i % 4;
                uint16_t nodeIdOffset = i / 4;
                preDefinedCanId = (CO_CAN_ID_TPDO_1 + pdoOffset * 0x100)
                                + nodeId + nodeIdOffset;
#endif
            }
            err = CO_TPDO_init(&co->TPDO[i],
                               od,
                               em,
 #if (CO_CONFIG_PDO) & CO_CONFIG_PDO_SYNC_ENABLE
                               co->SYNC,
 #endif
                               preDefinedCanId,
                               TPDOcomm++,
                               TPDOmap++,
                               co->CANmodule,
                               CO_GET_CO(TX_IDX_TPDO) + i,
                               errInfo);
            if (err) return err;
        }
    }
#endif

    return CO_ERROR_NO;
}


/******************************************************************************/
CO_NMT_reset_cmd_t CO_process(CO_t *co,
                              bool_t enableGateway,
                              uint32_t timeDifference_us,
                              uint32_t *timerNext_us)
{
    (void) enableGateway; /* may be unused */
    CO_NMT_reset_cmd_t reset = CO_RESET_NOT;
    CO_NMT_internalState_t NMTstate = CO_NMT_getInternalState(co->NMT);
    bool_t NMTisPreOrOperational = (NMTstate == CO_NMT_PRE_OPERATIONAL
                                    || NMTstate == CO_NMT_OPERATIONAL);

    /* CAN module */
    CO_CANmodule_process(co->CANmodule);

#if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    if (CO_GET_CNT(LSS_SLV) == 1) {
        if (CO_LSSslave_process(co->LSSslave)) {
            reset = CO_RESET_COMM;
        }
    }
#endif

#if (CO_CONFIG_LEDS) & CO_CONFIG_LEDS_ENABLE
    bool_t unc = co->nodeIdUnconfigured;
    uint16_t CANerrorStatus = co->CANmodule->CANerrorStatus;
    bool_t LSSslave_configuration = false;
 #if (CO_CONFIG_LSS) & CO_CONFIG_LSS_SLAVE
    if (CO_GET_CNT(LSS_SLV) == 1
        && CO_LSSslave_getState(co->LSSslave) == CO_LSS_STATE_CONFIGURATION
    ) {
        LSSslave_configuration = true;
    }
 #endif
 /* default macro, can be defined externally */
 #ifndef CO_STATUS_FIRMWARE_DOWNLOAD_IN_PROGRESS
  #define CO_STATUS_FIRMWARE_DOWNLOAD_IN_PROGRESS 0
 #endif

    if (CO_GET_CNT(LEDS) == 1) {
        CO_LEDs_process(co->LEDs,
            timeDifference_us,
            unc ? CO_NMT_INITIALIZING : NMTstate,
            LSSslave_configuration,
            (CANerrorStatus & CO_CAN_ERRTX_BUS_OFF) != 0,
            (CANerrorStatus & CO_CAN_ERR_WARN_PASSIVE) != 0,
            0, /* RPDO event timer timeout */
            unc ? false : CO_isError(co->em, CO_EM_SYNC_TIME_OUT),
            unc ? false : (CO_isError(co->em, CO_EM_HEARTBEAT_CONSUMER)
                        || CO_isError(co->em, CO_EM_HB_CONSUMER_REMOTE_RESET)),
            CO_getErrorRegister(co->em) != 0,
            CO_STATUS_FIRMWARE_DOWNLOAD_IN_PROGRESS,
            timerNext_us);
    }
#endif

    /* CANopen Node ID is unconfigured (LSS slave), stop processing here */
    if (co->nodeIdUnconfigured) {
        return reset;
    }

    /* Emergency */
    if (CO_GET_CNT(EM) == 1) {
        CO_EM_process(co->em,
                      NMTisPreOrOperational,
                      timeDifference_us,
                      timerNext_us);
    }

    /* NMT_Heartbeat */
    if (CO_GET_CNT(NMT) == 1) {
        reset = CO_NMT_process(co->NMT,
                               &NMTstate,
                               timeDifference_us,
                               timerNext_us);
    }
    NMTisPreOrOperational = (NMTstate == CO_NMT_PRE_OPERATIONAL
                             || NMTstate == CO_NMT_OPERATIONAL);

    /* SDOserver */
    for (uint8_t i = 0; i < CO_GET_CNT(SDO_SRV); i++) {
        CO_SDOserver_process(&co->SDOserver[i],
                             NMTisPreOrOperational,
                             timeDifference_us,
                             timerNext_us);
    }

#if (CO_CONFIG_HB_CONS) & CO_CONFIG_HB_CONS_ENABLE
    if (CO_GET_CNT(HB_CONS) == 1) {
        CO_HBconsumer_process(co->HBcons,
                              NMTisPreOrOperational,
                              timeDifference_us,
                              timerNext_us);
    }
#endif

#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_SLAVE_ENABLE
    CO_nodeGuardingSlave_process(co->NGslave,
                                 NMTstate,
                                 (co->NMT->HBproducerTime_us > 0),
                                 timeDifference_us,
                                 timerNext_us);
#endif
#if (CO_CONFIG_NODE_GUARDING) & CO_CONFIG_NODE_GUARDING_MASTER_ENABLE
    CO_nodeGuardingMaster_process(co->NGmaster,
                                  timeDifference_us,
                                  timerNext_us);
#endif

#if (CO_CONFIG_TIME) & CO_CONFIG_TIME_ENABLE
    if (CO_GET_CNT(TIME) == 1) {
        CO_TIME_process(co->TIME, NMTisPreOrOperational, timeDifference_us);
    }
#endif

#if (CO_CONFIG_GTW) & CO_CONFIG_GTW_ASCII
    if (CO_GET_CNT(GTWA) == 1) {
        CO_GTWA_process(co->gtwa,
                        enableGateway,
                        timeDifference_us,
                        timerNext_us);
    }
#endif

    return reset;
}


/******************************************************************************/
#if (CO_CONFIG_SYNC) & CO_CONFIG_SYNC_ENABLE
bool_t CO_process_SYNC(CO_t *co,
                       uint32_t timeDifference_us,
                       uint32_t *timerNext_us)
{
    bool_t syncWas = false;

    if (!co->nodeIdUnconfigured && CO_GET_CNT(SYNC) == 1) {
        CO_NMT_internalState_t NMTstate = CO_NMT_getInternalState(co->NMT);
        bool_t NMTisPreOrOperational = (NMTstate == CO_NMT_PRE_OPERATIONAL
                                        || NMTstate == CO_NMT_OPERATIONAL);

        CO_SYNC_status_t sync_process = CO_SYNC_process(co->SYNC,
                                                        NMTisPreOrOperational,
                                                        timeDifference_us,
                                                        timerNext_us);

        switch (sync_process) {
            case CO_SYNC_NONE:
                break;
            case CO_SYNC_RX_TX:
                syncWas = true;
                break;
            case CO_SYNC_PASSED_WINDOW:
                CO_CANclearPendingSyncPDOs(co->CANmodule);
                break;
        }
    }

    return syncWas;
}
#endif


/******************************************************************************/
#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_ENABLE
void CO_process_RPDO(CO_t *co,
                     bool_t syncWas,
                     uint32_t timeDifference_us,
                     uint32_t *timerNext_us)
{
    (void) timeDifference_us; (void) timerNext_us;
    if (co->nodeIdUnconfigured) {
        return;
    }

    bool_t NMTisOperational =
        CO_NMT_getInternalState(co->NMT) == CO_NMT_OPERATIONAL;

    for (int16_t i = 0; i < CO_GET_CNT(RPDO); i++) {
        CO_RPDO_process(&co->RPDO[i],
#if (CO_CONFIG_PDO) & CO_CONFIG_RPDO_TIMERS_ENABLE
                        timeDifference_us,
                        timerNext_us,
#endif
                        NMTisOperational,
                        syncWas);
    }
}
#endif


/******************************************************************************/
#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_ENABLE
void CO_process_TPDO(CO_t *co,
                     bool_t syncWas,
                     uint32_t timeDifference_us,
                     uint32_t *timerNext_us)
{
    (void) timeDifference_us; (void) timerNext_us;
    if (co->nodeIdUnconfigured) {
        return;
    }

    bool_t NMTisOperational =
        CO_NMT_getInternalState(co->NMT) == CO_NMT_OPERATIONAL;

    for (int16_t i = 0; i < CO_GET_CNT(TPDO); i++) {
        CO_TPDO_process(&co->TPDO[i],
#if (CO_CONFIG_PDO) & CO_CONFIG_TPDO_TIMERS_ENABLE
                        timeDifference_us,
                        timerNext_us,
#endif
                        NMTisOperational,
                        syncWas);
    }
}
#endif


/******************************************************************************/
#if (CO_CONFIG_SRDO) & CO_CONFIG_SRDO_ENABLE
void CO_process_SRDO(CO_t *co,
                     uint32_t timeDifference_us,
                     uint32_t *timerNext_us)
{
    if (co->nodeIdUnconfigured) {
        return;
    }

    uint8_t firstOperational = CO_SRDOGuard_process(co->SRDOGuard);

    for (int16_t i = 0; i < CO_GET_CNT(SRDO); i++) {
        CO_SRDO_process(&co->SRDO[i],
                        firstOperational,
                        timeDifference_us,
                        timerNext_us);
    }
}
#endif