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bacnet_stack/src/bacnet/basic/object/av.c
T
Steve Karg 810a2f93de Feature/write property type check refactor (#182) 
* refactor write-property tag check

* modify ports objects to use write-property tag check API

* modify example objects to use write-property tag check API

* Fix object unit test builds

* Fix and run unit ztests via CMake

* Enable unit testing on Travis CI

Co-authored-by: Steve Karg <skarg@users.sourceforge.net>
2021-06-23 10:10:12 -05:00

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/**************************************************************************
*
* Copyright (C) 2006 Steve Karg <skarg@users.sourceforge.net>
* Copyright (C) 2011 Krzysztof Malorny <malornykrzysztof@gmail.com>
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
*********************************************************************/
/* Analog Value Objects - customize for your use */
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include "bacnet/bacdef.h"
#include "bacnet/bacdcode.h"
#include "bacnet/bacenum.h"
#include "bacnet/bacapp.h"
#include "bacnet/bactext.h"
#include "bacnet/config.h" /* the custom stuff */
#include "bacnet/basic/object/device.h"
#include "bacnet/basic/services.h"
#include "bacnet/basic/object/av.h"
#ifndef MAX_ANALOG_VALUES
#define MAX_ANALOG_VALUES 4
#endif
static ANALOG_VALUE_DESCR AV_Descr[MAX_ANALOG_VALUES];
/* These three arrays are used by the ReadPropertyMultiple handler */
static const int Analog_Value_Properties_Required[] = { PROP_OBJECT_IDENTIFIER,
PROP_OBJECT_NAME, PROP_OBJECT_TYPE, PROP_PRESENT_VALUE, PROP_STATUS_FLAGS,
PROP_EVENT_STATE, PROP_OUT_OF_SERVICE, PROP_UNITS, -1 };
static const int Analog_Value_Properties_Optional[] = { PROP_DESCRIPTION,
PROP_COV_INCREMENT,
#if defined(INTRINSIC_REPORTING)
PROP_TIME_DELAY, PROP_NOTIFICATION_CLASS, PROP_HIGH_LIMIT, PROP_LOW_LIMIT,
PROP_DEADBAND, PROP_LIMIT_ENABLE, PROP_EVENT_ENABLE, PROP_ACKED_TRANSITIONS,
PROP_NOTIFY_TYPE, PROP_EVENT_TIME_STAMPS,
#endif
-1 };
static const int Analog_Value_Properties_Proprietary[] = { -1 };
/**
* Initialize the pointers for the required, the optional and the properitary
* value properties.
*
* @param pRequired - Pointer to the pointer of required values.
* @param pOptional - Pointer to the pointer of optional values.
* @param pProprietary - Pointer to the pointer of properitary values.
*/
void Analog_Value_Property_Lists(
const int **pRequired, const int **pOptional, const int **pProprietary)
{
if (pRequired) {
*pRequired = Analog_Value_Properties_Required;
}
if (pOptional) {
*pOptional = Analog_Value_Properties_Optional;
}
if (pProprietary) {
*pProprietary = Analog_Value_Properties_Proprietary;
}
return;
}
/**
* Initialize the analog values.
*/
void Analog_Value_Init(void)
{
unsigned i;
#if defined(INTRINSIC_REPORTING)
unsigned j;
#endif
for (i = 0; i < MAX_ANALOG_VALUES; i++) {
memset(&AV_Descr[i], 0x00, sizeof(ANALOG_VALUE_DESCR));
AV_Descr[i].Present_Value = 0.0;
AV_Descr[i].Units = UNITS_NO_UNITS;
AV_Descr[i].Prior_Value = 0.0f;
AV_Descr[i].COV_Increment = 1.0f;
AV_Descr[i].Changed = false;
#if defined(INTRINSIC_REPORTING)
AV_Descr[i].Event_State = EVENT_STATE_NORMAL;
/* notification class not connected */
AV_Descr[i].Notification_Class = BACNET_MAX_INSTANCE;
/* initialize Event time stamps using wildcards
and set Acked_transitions */
for (j = 0; j < MAX_BACNET_EVENT_TRANSITION; j++) {
datetime_wildcard_set(&AV_Descr[i].Event_Time_Stamps[j]);
AV_Descr[i].Acked_Transitions[j].bIsAcked = true;
}
/* Set handler for GetEventInformation function */
handler_get_event_information_set(
OBJECT_ANALOG_VALUE, Analog_Value_Event_Information);
/* Set handler for AcknowledgeAlarm function */
handler_alarm_ack_set(OBJECT_ANALOG_VALUE, Analog_Value_Alarm_Ack);
/* Set handler for GetAlarmSummary Service */
handler_get_alarm_summary_set(
OBJECT_ANALOG_VALUE, Analog_Value_Alarm_Summary);
#endif
}
}
/**
* We simply have 0-n object instances. Yours might be
* more complex, and then you need validate that the
* given instance exists.
*
* @param object_instance Object instance
*
* @return true/false
*/
bool Analog_Value_Valid_Instance(uint32_t object_instance)
{
if (object_instance < MAX_ANALOG_VALUES) {
return true;
}
return false;
}
/**
* Return the count of analog values.
*
* @return Count of analog values.
*/
unsigned Analog_Value_Count(void)
{
return MAX_ANALOG_VALUES;
}
/**
* We simply have 0-n object instances. Yours might be
* more complex, and then you need to return the instance
* that correlates to the correct index.
*
* @param index Index
*
* @return Object instance
*/
uint32_t Analog_Value_Index_To_Instance(unsigned index)
{
return index;
}
/**
* We simply have 0-n object instances. Yours might be
* more complex, and then you need to return the index
* that correlates to the correct instance number
*
* @param object_instance Object instance
*
* @return Index in the object table.
*/
unsigned Analog_Value_Instance_To_Index(uint32_t object_instance)
{
unsigned index = MAX_ANALOG_VALUES;
if (object_instance < MAX_ANALOG_VALUES) {
index = object_instance;
}
return index;
}
/**
* This function is used to detect a value change,
* using the new value compared against the prior
* value, using a delta as threshold.
*
* This method will update the COV-changed attribute.
*
* @param index Object index
* @param value Given present value.
*/
static void Analog_Value_COV_Detect(unsigned int index, float value)
{
float prior_value = 0.0;
float cov_increment = 0.0;
float cov_delta = 0.0;
if (index < MAX_ANALOG_VALUES) {
prior_value = AV_Descr[index].Prior_Value;
cov_increment = AV_Descr[index].COV_Increment;
if (prior_value > value) {
cov_delta = prior_value - value;
} else {
cov_delta = value - prior_value;
}
if (cov_delta >= cov_increment) {
AV_Descr[index].Changed = true;
AV_Descr[index].Prior_Value = value;
}
}
}
/**
* For a given object instance-number, sets the present-value at a given
* priority 1..16.
*
* @param object_instance - object-instance number of the object
* @param value - floating point analog value
* @param priority - priority 1..16
*
* @return true if values are within range and present-value is set.
*/
bool Analog_Value_Present_Value_Set(
uint32_t object_instance, float value, uint8_t priority)
{
unsigned index = 0;
bool status = false;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
Analog_Value_COV_Detect(index, value);
AV_Descr[index].Present_Value = value;
status = true;
}
return status;
}
/**
* For a given object instance-number, return the present value.
*
* @param object_instance - object-instance number of the object
*
* @return Present value
*/
float Analog_Value_Present_Value(uint32_t object_instance)
{
float value = 0;
unsigned index = 0;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
value = AV_Descr[index].Present_Value;
}
return value;
}
/**
* For a given object instance-number, return the name.
*
* Note: the object name must be unique within this device
*
* @param object_instance - object-instance number of the object
* @param object_name - object name/string pointer
*
* @return true/false
*/
bool Analog_Value_Object_Name(
uint32_t object_instance, BACNET_CHARACTER_STRING *object_name)
{
static char text_string[32] = ""; /* okay for single thread */
bool status = false;
if (object_instance < MAX_ANALOG_VALUES) {
sprintf(
text_string, "ANALOG VALUE %lu", (unsigned long)object_instance);
status = characterstring_init_ansi(object_name, text_string);
}
return status;
}
/**
* For a given object instance-number, gets the event-state property value
*
* @param object_instance - object-instance number of the object
*
* @return event-state property value
*/
unsigned Analog_Value_Event_State(uint32_t object_instance)
{
unsigned index = 0;
unsigned state = EVENT_STATE_NORMAL;
#if defined(INTRINSIC_REPORTING)
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
state = AV_Descr[index].Event_State;
}
#endif
return state;
}
/**
* For a given object instance-number, determines if the COV flag
* has been triggered.
*
* @param object_instance - object-instance number of the object
*
* @return true if the COV flag is set
*/
bool Analog_Value_Change_Of_Value(uint32_t object_instance)
{
unsigned index = 0;
bool changed = false;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
changed = AV_Descr[index].Changed;
}
return changed;
}
/**
* For a given object instance-number, clears the COV flag
*
* @param object_instance - object-instance number of the object
*/
void Analog_Value_Change_Of_Value_Clear(uint32_t object_instance)
{
unsigned index = 0;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
AV_Descr[index].Changed = false;
}
}
/**
* For a given object instance-number, loads the value_list with the COV data.
*
* @param object_instance - object-instance number of the object
* @param value_list - list of COV data
*
* @return true if the value list is encoded
*/
bool Analog_Value_Encode_Value_List(
uint32_t object_instance, BACNET_PROPERTY_VALUE *value_list)
{
bool status = false;
if (value_list) {
value_list->propertyIdentifier = PROP_PRESENT_VALUE;
value_list->propertyArrayIndex = BACNET_ARRAY_ALL;
value_list->value.context_specific = false;
value_list->value.tag = BACNET_APPLICATION_TAG_REAL;
value_list->value.type.Real =
Analog_Value_Present_Value(object_instance);
value_list->value.next = NULL;
value_list->priority = BACNET_NO_PRIORITY;
value_list = value_list->next;
}
if (value_list) {
value_list->propertyIdentifier = PROP_STATUS_FLAGS;
value_list->propertyArrayIndex = BACNET_ARRAY_ALL;
value_list->value.context_specific = false;
value_list->value.tag = BACNET_APPLICATION_TAG_BIT_STRING;
bitstring_init(&value_list->value.type.Bit_String);
if (Analog_Value_Event_State(object_instance) == EVENT_STATE_NORMAL) {
bitstring_set_bit(&value_list->value.type.Bit_String,
STATUS_FLAG_IN_ALARM, false);
} else {
bitstring_set_bit(&value_list->value.type.Bit_String,
STATUS_FLAG_IN_ALARM, true);
}
bitstring_set_bit(
&value_list->value.type.Bit_String, STATUS_FLAG_FAULT, false);
bitstring_set_bit(
&value_list->value.type.Bit_String, STATUS_FLAG_OVERRIDDEN, false);
if (Analog_Value_Out_Of_Service(object_instance)) {
bitstring_set_bit(&value_list->value.type.Bit_String,
STATUS_FLAG_OUT_OF_SERVICE, true);
} else {
bitstring_set_bit(&value_list->value.type.Bit_String,
STATUS_FLAG_OUT_OF_SERVICE, false);
}
value_list->value.next = NULL;
value_list->priority = BACNET_NO_PRIORITY;
value_list->next = NULL;
status = true;
}
return status;
}
float Analog_Value_COV_Increment(uint32_t object_instance)
{
unsigned index = 0;
float value = 0;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
value = AV_Descr[index].COV_Increment;
}
return value;
}
void Analog_Value_COV_Increment_Set(uint32_t object_instance, float value)
{
unsigned index = 0;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
AV_Descr[index].COV_Increment = value;
Analog_Value_COV_Detect(index, AV_Descr[index].Present_Value);
}
}
bool Analog_Value_Out_Of_Service(uint32_t object_instance)
{
unsigned index = 0;
bool value = false;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
value = AV_Descr[index].Out_Of_Service;
}
return value;
}
void Analog_Value_Out_Of_Service_Set(uint32_t object_instance, bool value)
{
unsigned index = 0;
index = Analog_Value_Instance_To_Index(object_instance);
if (index < MAX_ANALOG_VALUES) {
if (AV_Descr[index].Out_Of_Service != value) {
AV_Descr[index].Changed = true;
}
AV_Descr[index].Out_Of_Service = value;
}
}
/**
* Return the requested property of the analog value.
*
* @param rpdata Property requested, see for BACNET_READ_PROPERTY_DATA details.
*
* @return apdu len, or BACNET_STATUS_ERROR on error
*/
int Analog_Value_Read_Property(BACNET_READ_PROPERTY_DATA *rpdata)
{
int apdu_len = 0; /* return value */
BACNET_BIT_STRING bit_string;
BACNET_CHARACTER_STRING char_string;
float real_value = (float)1.414;
unsigned object_index = 0;
bool state = false;
uint8_t *apdu = NULL;
ANALOG_VALUE_DESCR *CurrentAV;
#if defined(INTRINSIC_REPORTING)
int len = 0;
unsigned i = 0;
#endif
/* Valid data? */
if (rpdata == NULL) {
return 0;
}
if ((rpdata->application_data == NULL) ||
(rpdata->application_data_len == 0)) {
return 0;
}
apdu = rpdata->application_data;
object_index = Analog_Value_Instance_To_Index(rpdata->object_instance);
if (object_index >= MAX_ANALOG_VALUES) {
rpdata->error_class = ERROR_CLASS_OBJECT;
rpdata->error_code = ERROR_CODE_UNKNOWN_OBJECT;
return BACNET_STATUS_ERROR;
}
CurrentAV = &AV_Descr[object_index];
switch (rpdata->object_property) {
case PROP_OBJECT_IDENTIFIER:
apdu_len = encode_application_object_id(
&apdu[0], OBJECT_ANALOG_VALUE, rpdata->object_instance);
break;
case PROP_OBJECT_NAME:
case PROP_DESCRIPTION:
if (Analog_Value_Object_Name(
rpdata->object_instance, &char_string)) {
apdu_len =
encode_application_character_string(&apdu[0], &char_string);
}
break;
case PROP_OBJECT_TYPE:
apdu_len =
encode_application_enumerated(&apdu[0], OBJECT_ANALOG_VALUE);
break;
case PROP_PRESENT_VALUE:
real_value = Analog_Value_Present_Value(rpdata->object_instance);
apdu_len = encode_application_real(&apdu[0], real_value);
break;
case PROP_STATUS_FLAGS:
bitstring_init(&bit_string);
bitstring_set_bit(&bit_string, STATUS_FLAG_IN_ALARM,
Analog_Value_Event_State(rpdata->object_instance) !=
EVENT_STATE_NORMAL);
bitstring_set_bit(&bit_string, STATUS_FLAG_FAULT, false);
bitstring_set_bit(&bit_string, STATUS_FLAG_OVERRIDDEN, false);
bitstring_set_bit(&bit_string, STATUS_FLAG_OUT_OF_SERVICE,
CurrentAV->Out_Of_Service);
apdu_len = encode_application_bitstring(&apdu[0], &bit_string);
break;
case PROP_EVENT_STATE:
#if defined(INTRINSIC_REPORTING)
apdu_len =
encode_application_enumerated(&apdu[0], CurrentAV->Event_State);
#else
apdu_len =
encode_application_enumerated(&apdu[0], EVENT_STATE_NORMAL);
#endif
break;
case PROP_OUT_OF_SERVICE:
state = CurrentAV->Out_Of_Service;
apdu_len = encode_application_boolean(&apdu[0], state);
break;
case PROP_UNITS:
apdu_len =
encode_application_enumerated(&apdu[0], CurrentAV->Units);
break;
case PROP_COV_INCREMENT:
apdu_len =
encode_application_real(&apdu[0], CurrentAV->COV_Increment);
break;
#if defined(INTRINSIC_REPORTING)
case PROP_TIME_DELAY:
apdu_len =
encode_application_unsigned(&apdu[0], CurrentAV->Time_Delay);
break;
case PROP_NOTIFICATION_CLASS:
apdu_len = encode_application_unsigned(
&apdu[0], CurrentAV->Notification_Class);
break;
case PROP_HIGH_LIMIT:
apdu_len = encode_application_real(&apdu[0], CurrentAV->High_Limit);
break;
case PROP_LOW_LIMIT:
apdu_len = encode_application_real(&apdu[0], CurrentAV->Low_Limit);
break;
case PROP_DEADBAND:
apdu_len = encode_application_real(&apdu[0], CurrentAV->Deadband);
break;
case PROP_LIMIT_ENABLE:
bitstring_init(&bit_string);
bitstring_set_bit(&bit_string, 0,
(CurrentAV->Limit_Enable & EVENT_LOW_LIMIT_ENABLE) ? true
: false);
bitstring_set_bit(&bit_string, 1,
(CurrentAV->Limit_Enable & EVENT_HIGH_LIMIT_ENABLE) ? true
: false);
apdu_len = encode_application_bitstring(&apdu[0], &bit_string);
break;
case PROP_EVENT_ENABLE:
bitstring_init(&bit_string);
bitstring_set_bit(&bit_string, TRANSITION_TO_OFFNORMAL,
(CurrentAV->Event_Enable & EVENT_ENABLE_TO_OFFNORMAL) ? true
: false);
bitstring_set_bit(&bit_string, TRANSITION_TO_FAULT,
(CurrentAV->Event_Enable & EVENT_ENABLE_TO_FAULT) ? true
: false);
bitstring_set_bit(&bit_string, TRANSITION_TO_NORMAL,
(CurrentAV->Event_Enable & EVENT_ENABLE_TO_NORMAL) ? true
: false);
apdu_len = encode_application_bitstring(&apdu[0], &bit_string);
break;
case PROP_ACKED_TRANSITIONS:
bitstring_init(&bit_string);
bitstring_set_bit(&bit_string, TRANSITION_TO_OFFNORMAL,
CurrentAV->Acked_Transitions[TRANSITION_TO_OFFNORMAL].bIsAcked);
bitstring_set_bit(&bit_string, TRANSITION_TO_FAULT,
CurrentAV->Acked_Transitions[TRANSITION_TO_FAULT].bIsAcked);
bitstring_set_bit(&bit_string, TRANSITION_TO_NORMAL,
CurrentAV->Acked_Transitions[TRANSITION_TO_NORMAL].bIsAcked);
apdu_len = encode_application_bitstring(&apdu[0], &bit_string);
break;
case PROP_NOTIFY_TYPE:
apdu_len = encode_application_enumerated(
&apdu[0], CurrentAV->Notify_Type ? NOTIFY_EVENT : NOTIFY_ALARM);
break;
case PROP_EVENT_TIME_STAMPS:
/* Array element zero is the number of elements in the array */
if (rpdata->array_index == 0)
apdu_len = encode_application_unsigned(
&apdu[0], MAX_BACNET_EVENT_TRANSITION);
/* if no index was specified, then try to encode the entire list */
/* into one packet. */
else if (rpdata->array_index == BACNET_ARRAY_ALL) {
for (i = 0; i < MAX_BACNET_EVENT_TRANSITION; i++) {
len = encode_opening_tag(
&apdu[apdu_len], TIME_STAMP_DATETIME);
len += encode_application_date(&apdu[apdu_len + len],
&CurrentAV->Event_Time_Stamps[i].date);
len += encode_application_time(&apdu[apdu_len + len],
&CurrentAV->Event_Time_Stamps[i].time);
len += encode_closing_tag(
&apdu[apdu_len + len], TIME_STAMP_DATETIME);
/* add it if we have room */
if ((apdu_len + len) < MAX_APDU)
apdu_len += len;
else {
rpdata->error_code =
ERROR_CODE_ABORT_SEGMENTATION_NOT_SUPPORTED;
apdu_len = BACNET_STATUS_ABORT;
break;
}
}
} else if (rpdata->array_index <= MAX_BACNET_EVENT_TRANSITION) {
apdu_len =
encode_opening_tag(&apdu[apdu_len], TIME_STAMP_DATETIME);
apdu_len += encode_application_date(&apdu[apdu_len],
&CurrentAV->Event_Time_Stamps[rpdata->array_index].date);
apdu_len += encode_application_time(&apdu[apdu_len],
&CurrentAV->Event_Time_Stamps[rpdata->array_index].time);
apdu_len +=
encode_closing_tag(&apdu[apdu_len], TIME_STAMP_DATETIME);
} else {
rpdata->error_class = ERROR_CLASS_PROPERTY;
rpdata->error_code = ERROR_CODE_INVALID_ARRAY_INDEX;
apdu_len = BACNET_STATUS_ERROR;
}
break;
#endif
default:
rpdata->error_class = ERROR_CLASS_PROPERTY;
rpdata->error_code = ERROR_CODE_UNKNOWN_PROPERTY;
apdu_len = BACNET_STATUS_ERROR;
break;
}
/* only array properties can have array options */
if ((apdu_len >= 0) && (rpdata->object_property != PROP_PRIORITY_ARRAY) &&
(rpdata->object_property != PROP_EVENT_TIME_STAMPS) &&
(rpdata->array_index != BACNET_ARRAY_ALL)) {
rpdata->error_class = ERROR_CLASS_PROPERTY;
rpdata->error_code = ERROR_CODE_PROPERTY_IS_NOT_AN_ARRAY;
apdu_len = BACNET_STATUS_ERROR;
}
return apdu_len;
}
/**
* Set the requested property of the analog value.
*
* @param wp_data Property requested, see for BACNET_WRITE_PROPERTY_DATA
* details.
*
* @return true if successful
*/
bool Analog_Value_Write_Property(BACNET_WRITE_PROPERTY_DATA *wp_data)
{
bool status = false; /* return value */
unsigned int object_index = 0;
int len = 0;
BACNET_APPLICATION_DATA_VALUE value;
ANALOG_VALUE_DESCR *CurrentAV;
/* Valid data? */
if (wp_data == NULL) {
return false;
}
if (wp_data->application_data_len == 0) {
return false;
}
/* decode the some of the request */
len = bacapp_decode_application_data(
wp_data->application_data, wp_data->application_data_len, &value);
/* FIXME: len < application_data_len: more data? */
if (len < 0) {
/* error while decoding - a value larger than we can handle */
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
return false;
}
if ((wp_data->object_property != PROP_PRIORITY_ARRAY) &&
(wp_data->object_property != PROP_EVENT_TIME_STAMPS) &&
(wp_data->array_index != BACNET_ARRAY_ALL)) {
/* only array properties can have array options */
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_PROPERTY_IS_NOT_AN_ARRAY;
return false;
}
/* Valid object? */
object_index = Analog_Value_Instance_To_Index(wp_data->object_instance);
if (object_index >= MAX_ANALOG_VALUES) {
wp_data->error_class = ERROR_CLASS_OBJECT;
wp_data->error_code = ERROR_CODE_UNKNOWN_OBJECT;
return false;
}
CurrentAV = &AV_Descr[object_index];
switch (wp_data->object_property) {
case PROP_PRESENT_VALUE:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_REAL);
if (status) {
/* Command priority 6 is reserved for use by Minimum On/Off
algorithm and may not be used for other purposes in any
object. */
if (Analog_Value_Present_Value_Set(wp_data->object_instance,
value.type.Real, wp_data->priority)) {
status = true;
} else if (wp_data->priority == 6) {
/* Command priority 6 is reserved for use by Minimum On/Off
algorithm and may not be used for other purposes in any
object. */
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_WRITE_ACCESS_DENIED;
} else {
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
}
} else {
status = false;
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
}
break;
case PROP_OUT_OF_SERVICE:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_BOOLEAN);
if (status) {
CurrentAV->Out_Of_Service = value.type.Boolean;
}
break;
case PROP_UNITS:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_ENUMERATED);
if (status) {
CurrentAV->Units = value.type.Enumerated;
}
break;
case PROP_COV_INCREMENT:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_REAL);
if (status) {
if (value.type.Real >= 0.0) {
Analog_Value_COV_Increment_Set(
wp_data->object_instance, value.type.Real);
} else {
status = false;
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
}
}
break;
#if defined(INTRINSIC_REPORTING)
case PROP_TIME_DELAY:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_UNSIGNED_INT);
if (status) {
CurrentAV->Time_Delay = value.type.Unsigned_Int;
CurrentAV->Remaining_Time_Delay = CurrentAV->Time_Delay;
}
break;
case PROP_NOTIFICATION_CLASS:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_UNSIGNED_INT);
if (status) {
CurrentAV->Notification_Class = value.type.Unsigned_Int;
}
break;
case PROP_HIGH_LIMIT:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_REAL);
if (status) {
CurrentAV->High_Limit = value.type.Real;
}
break;
case PROP_LOW_LIMIT:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_REAL);
if (status) {
CurrentAV->Low_Limit = value.type.Real;
}
break;
case PROP_DEADBAND:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_REAL);
if (status) {
CurrentAV->Deadband = value.type.Real;
}
break;
case PROP_LIMIT_ENABLE:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_BIT_STRING);
if (status) {
if (value.type.Bit_String.bits_used == 2) {
CurrentAV->Limit_Enable = value.type.Bit_String.value[0];
} else {
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
status = false;
}
}
break;
case PROP_EVENT_ENABLE:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_BIT_STRING);
if (status) {
if (value.type.Bit_String.bits_used == 3) {
CurrentAV->Event_Enable = value.type.Bit_String.value[0];
} else {
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
status = false;
}
}
break;
case PROP_NOTIFY_TYPE:
status = write_property_type_valid(wp_data, &value,
BACNET_APPLICATION_TAG_ENUMERATED);
if (status) {
switch ((BACNET_NOTIFY_TYPE)value.type.Enumerated) {
case NOTIFY_EVENT:
CurrentAV->Notify_Type = 1;
break;
case NOTIFY_ALARM:
CurrentAV->Notify_Type = 0;
break;
default:
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_VALUE_OUT_OF_RANGE;
status = false;
break;
}
}
break;
#endif
case PROP_OBJECT_IDENTIFIER:
case PROP_OBJECT_NAME:
case PROP_OBJECT_TYPE:
case PROP_STATUS_FLAGS:
case PROP_EVENT_STATE:
case PROP_DESCRIPTION:
#if defined(INTRINSIC_REPORTING)
case PROP_ACKED_TRANSITIONS:
case PROP_EVENT_TIME_STAMPS:
#endif
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_WRITE_ACCESS_DENIED;
break;
case PROP_RELINQUISH_DEFAULT:
case PROP_PRIORITY_ARRAY:
default:
wp_data->error_class = ERROR_CLASS_PROPERTY;
wp_data->error_code = ERROR_CODE_UNKNOWN_PROPERTY;
break;
}
return status;
}
void Analog_Value_Intrinsic_Reporting(uint32_t object_instance)
{
#if defined(INTRINSIC_REPORTING)
BACNET_EVENT_NOTIFICATION_DATA event_data;
BACNET_CHARACTER_STRING msgText;
ANALOG_VALUE_DESCR *CurrentAV;
unsigned int object_index;
uint8_t FromState = 0;
uint8_t ToState;
float ExceededLimit = 0.0f;
float PresentVal = 0.0f;
bool SendNotify = false;
object_index = Analog_Value_Instance_To_Index(object_instance);
if (object_index < MAX_ANALOG_VALUES)
CurrentAV = &AV_Descr[object_index];
else
return;
/* check limits */
if (!CurrentAV->Limit_Enable)
return; /* limits are not configured */
if (CurrentAV->Ack_notify_data.bSendAckNotify) {
/* clean bSendAckNotify flag */
CurrentAV->Ack_notify_data.bSendAckNotify = false;
/* copy toState */
ToState = CurrentAV->Ack_notify_data.EventState;
#if PRINT_ENABLED
fprintf(stderr, "Send Acknotification for (%s,%d).\n",
bactext_object_type_name(OBJECT_ANALOG_VALUE), object_instance);
#endif /* PRINT_ENABLED */
characterstring_init_ansi(&msgText, "AckNotification");
/* Notify Type */
event_data.notifyType = NOTIFY_ACK_NOTIFICATION;
/* Send EventNotification. */
SendNotify = true;
} else {
/* actual Present_Value */
PresentVal = Analog_Value_Present_Value(object_instance);
FromState = CurrentAV->Event_State;
switch (CurrentAV->Event_State) {
case EVENT_STATE_NORMAL:
/* A TO-OFFNORMAL event is generated under these conditions:
(a) the Present_Value must exceed the High_Limit for a
minimum period of time, specified in the Time_Delay property,
and (b) the HighLimitEnable flag must be set in the
Limit_Enable property, and
(c) the TO-OFFNORMAL flag must be set in the Event_Enable
property. */
if ((PresentVal > CurrentAV->High_Limit) &&
((CurrentAV->Limit_Enable & EVENT_HIGH_LIMIT_ENABLE) ==
EVENT_HIGH_LIMIT_ENABLE) &&
((CurrentAV->Event_Enable & EVENT_ENABLE_TO_OFFNORMAL) ==
EVENT_ENABLE_TO_OFFNORMAL)) {
if (!CurrentAV->Remaining_Time_Delay)
CurrentAV->Event_State = EVENT_STATE_HIGH_LIMIT;
else
CurrentAV->Remaining_Time_Delay--;
break;
}
/* A TO-OFFNORMAL event is generated under these conditions:
(a) the Present_Value must exceed the Low_Limit plus the
Deadband for a minimum period of time, specified in the
Time_Delay property, and (b) the LowLimitEnable flag must be
set in the Limit_Enable property, and
(c) the TO-NORMAL flag must be set in the Event_Enable
property. */
if ((PresentVal < CurrentAV->Low_Limit) &&
((CurrentAV->Limit_Enable & EVENT_LOW_LIMIT_ENABLE) ==
EVENT_LOW_LIMIT_ENABLE) &&
((CurrentAV->Event_Enable & EVENT_ENABLE_TO_OFFNORMAL) ==
EVENT_ENABLE_TO_OFFNORMAL)) {
if (!CurrentAV->Remaining_Time_Delay)
CurrentAV->Event_State = EVENT_STATE_LOW_LIMIT;
else
CurrentAV->Remaining_Time_Delay--;
break;
}
/* value of the object is still in the same event state */
CurrentAV->Remaining_Time_Delay = CurrentAV->Time_Delay;
break;
case EVENT_STATE_HIGH_LIMIT:
/* Once exceeded, the Present_Value must fall below the
High_Limit minus the Deadband before a TO-NORMAL event is
generated under these conditions: (a) the Present_Value must
fall below the High_Limit minus the Deadband for a minimum
period of time, specified in the Time_Delay property, and (b)
the HighLimitEnable flag must be set in the Limit_Enable
property, and (c) the TO-NORMAL flag must be set in the
Event_Enable property. */
if ((PresentVal <
CurrentAV->High_Limit - CurrentAV->Deadband) &&
((CurrentAV->Limit_Enable & EVENT_HIGH_LIMIT_ENABLE) ==
EVENT_HIGH_LIMIT_ENABLE) &&
((CurrentAV->Event_Enable & EVENT_ENABLE_TO_NORMAL) ==
EVENT_ENABLE_TO_NORMAL)) {
if (!CurrentAV->Remaining_Time_Delay)
CurrentAV->Event_State = EVENT_STATE_NORMAL;
else
CurrentAV->Remaining_Time_Delay--;
break;
}
/* value of the object is still in the same event state */
CurrentAV->Remaining_Time_Delay = CurrentAV->Time_Delay;
break;
case EVENT_STATE_LOW_LIMIT:
/* Once the Present_Value has fallen below the Low_Limit,
the Present_Value must exceed the Low_Limit plus the Deadband
before a TO-NORMAL event is generated under these conditions:
(a) the Present_Value must exceed the Low_Limit plus the
Deadband for a minimum period of time, specified in the
Time_Delay property, and (b) the LowLimitEnable flag must be
set in the Limit_Enable property, and
(c) the TO-NORMAL flag must be set in the Event_Enable
property. */
if ((PresentVal > CurrentAV->Low_Limit + CurrentAV->Deadband) &&
((CurrentAV->Limit_Enable & EVENT_LOW_LIMIT_ENABLE) ==
EVENT_LOW_LIMIT_ENABLE) &&
((CurrentAV->Event_Enable & EVENT_ENABLE_TO_NORMAL) ==
EVENT_ENABLE_TO_NORMAL)) {
if (!CurrentAV->Remaining_Time_Delay)
CurrentAV->Event_State = EVENT_STATE_NORMAL;
else
CurrentAV->Remaining_Time_Delay--;
break;
}
/* value of the object is still in the same event state */
CurrentAV->Remaining_Time_Delay = CurrentAV->Time_Delay;
break;
default:
return; /* shouldn't happen */
} /* switch (FromState) */
ToState = CurrentAV->Event_State;
if (FromState != ToState) {
/* Event_State has changed.
Need to fill only the basic parameters of this type of event.
Other parameters will be filled in common function. */
switch (ToState) {
case EVENT_STATE_HIGH_LIMIT:
ExceededLimit = CurrentAV->High_Limit;
characterstring_init_ansi(&msgText, "Goes to high limit");
break;
case EVENT_STATE_LOW_LIMIT:
ExceededLimit = CurrentAV->Low_Limit;
characterstring_init_ansi(&msgText, "Goes to low limit");
break;
case EVENT_STATE_NORMAL:
if (FromState == EVENT_STATE_HIGH_LIMIT) {
ExceededLimit = CurrentAV->High_Limit;
characterstring_init_ansi(
&msgText, "Back to normal state from high limit");
} else {
ExceededLimit = CurrentAV->Low_Limit;
characterstring_init_ansi(
&msgText, "Back to normal state from low limit");
}
break;
default:
ExceededLimit = 0;
break;
} /* switch (ToState) */
#if PRINT_ENABLED
fprintf(stderr, "Event_State for (%s,%d) goes from %s to %s.\n",
bactext_object_type_name(OBJECT_ANALOG_VALUE), object_instance,
bactext_event_state_name(FromState),
bactext_event_state_name(ToState));
#endif /* PRINT_ENABLED */
/* Notify Type */
event_data.notifyType = CurrentAV->Notify_Type;
/* Send EventNotification. */
SendNotify = true;
}
}
if (SendNotify) {
/* Event Object Identifier */
event_data.eventObjectIdentifier.type = OBJECT_ANALOG_VALUE;
event_data.eventObjectIdentifier.instance = object_instance;
/* Time Stamp */
event_data.timeStamp.tag = TIME_STAMP_DATETIME;
Device_getCurrentDateTime(&event_data.timeStamp.value.dateTime);
if (event_data.notifyType != NOTIFY_ACK_NOTIFICATION) {
/* fill Event_Time_Stamps */
switch (ToState) {
case EVENT_STATE_HIGH_LIMIT:
case EVENT_STATE_LOW_LIMIT:
CurrentAV->Event_Time_Stamps[TRANSITION_TO_OFFNORMAL] =
event_data.timeStamp.value.dateTime;
break;
case EVENT_STATE_FAULT:
CurrentAV->Event_Time_Stamps[TRANSITION_TO_FAULT] =
event_data.timeStamp.value.dateTime;
break;
case EVENT_STATE_NORMAL:
CurrentAV->Event_Time_Stamps[TRANSITION_TO_NORMAL] =
event_data.timeStamp.value.dateTime;
break;
}
}
/* Notification Class */
event_data.notificationClass = CurrentAV->Notification_Class;
/* Event Type */
event_data.eventType = EVENT_OUT_OF_RANGE;
/* Message Text */
event_data.messageText = &msgText;
/* Notify Type */
/* filled before */
/* From State */
if (event_data.notifyType != NOTIFY_ACK_NOTIFICATION)
event_data.fromState = FromState;
/* To State */
event_data.toState = CurrentAV->Event_State;
/* Event Values */
if (event_data.notifyType != NOTIFY_ACK_NOTIFICATION) {
/* Value that exceeded a limit. */
event_data.notificationParams.outOfRange.exceedingValue =
PresentVal;
/* Status_Flags of the referenced object. */
bitstring_init(
&event_data.notificationParams.outOfRange.statusFlags);
bitstring_set_bit(
&event_data.notificationParams.outOfRange.statusFlags,
STATUS_FLAG_IN_ALARM,
CurrentAV->Event_State != EVENT_STATE_NORMAL);
bitstring_set_bit(
&event_data.notificationParams.outOfRange.statusFlags,
STATUS_FLAG_FAULT, false);
bitstring_set_bit(
&event_data.notificationParams.outOfRange.statusFlags,
STATUS_FLAG_OVERRIDDEN, false);
bitstring_set_bit(
&event_data.notificationParams.outOfRange.statusFlags,
STATUS_FLAG_OUT_OF_SERVICE, CurrentAV->Out_Of_Service);
/* Deadband used for limit checking. */
event_data.notificationParams.outOfRange.deadband =
CurrentAV->Deadband;
/* Limit that was exceeded. */
event_data.notificationParams.outOfRange.exceededLimit =
ExceededLimit;
}
/* add data from notification class */
Notification_Class_common_reporting_function(&event_data);
/* Ack required */
if ((event_data.notifyType != NOTIFY_ACK_NOTIFICATION) &&
(event_data.ackRequired == true)) {
switch (event_data.toState) {
case EVENT_STATE_OFFNORMAL:
case EVENT_STATE_HIGH_LIMIT:
case EVENT_STATE_LOW_LIMIT:
CurrentAV->Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.bIsAcked = false;
CurrentAV->Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.Time_Stamp = event_data.timeStamp.value.dateTime;
break;
case EVENT_STATE_FAULT:
CurrentAV->Acked_Transitions[TRANSITION_TO_FAULT].bIsAcked =
false;
CurrentAV->Acked_Transitions[TRANSITION_TO_FAULT]
.Time_Stamp = event_data.timeStamp.value.dateTime;
break;
case EVENT_STATE_NORMAL:
CurrentAV->Acked_Transitions[TRANSITION_TO_NORMAL]
.bIsAcked = false;
CurrentAV->Acked_Transitions[TRANSITION_TO_NORMAL]
.Time_Stamp = event_data.timeStamp.value.dateTime;
break;
default: /* shouldn't happen */
break;
}
}
}
#endif /* defined(INTRINSIC_REPORTING) */
}
#if defined(INTRINSIC_REPORTING)
int Analog_Value_Event_Information(
unsigned index, BACNET_GET_EVENT_INFORMATION_DATA *getevent_data)
{
bool IsNotAckedTransitions;
bool IsActiveEvent;
int i;
/* check index */
if (index < MAX_ANALOG_VALUES) {
/* Event_State not equal to NORMAL */
IsActiveEvent = (AV_Descr[index].Event_State != EVENT_STATE_NORMAL);
/* Acked_Transitions property, which has at least one of the bits
(TO-OFFNORMAL, TO-FAULT, TONORMAL) set to FALSE. */
IsNotAckedTransitions =
(AV_Descr[index]
.Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.bIsAcked == false) |
(AV_Descr[index].Acked_Transitions[TRANSITION_TO_FAULT].bIsAcked ==
false) |
(AV_Descr[index].Acked_Transitions[TRANSITION_TO_NORMAL].bIsAcked ==
false);
} else
return -1; /* end of list */
if ((IsActiveEvent) || (IsNotAckedTransitions)) {
/* Object Identifier */
getevent_data->objectIdentifier.type = OBJECT_ANALOG_VALUE;
getevent_data->objectIdentifier.instance =
Analog_Value_Index_To_Instance(index);
/* Event State */
getevent_data->eventState = AV_Descr[index].Event_State;
/* Acknowledged Transitions */
bitstring_init(&getevent_data->acknowledgedTransitions);
bitstring_set_bit(&getevent_data->acknowledgedTransitions,
TRANSITION_TO_OFFNORMAL,
AV_Descr[index]
.Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.bIsAcked);
bitstring_set_bit(&getevent_data->acknowledgedTransitions,
TRANSITION_TO_FAULT,
AV_Descr[index].Acked_Transitions[TRANSITION_TO_FAULT].bIsAcked);
bitstring_set_bit(&getevent_data->acknowledgedTransitions,
TRANSITION_TO_NORMAL,
AV_Descr[index].Acked_Transitions[TRANSITION_TO_NORMAL].bIsAcked);
/* Event Time Stamps */
for (i = 0; i < 3; i++) {
getevent_data->eventTimeStamps[i].tag = TIME_STAMP_DATETIME;
getevent_data->eventTimeStamps[i].value.dateTime =
AV_Descr[index].Event_Time_Stamps[i];
}
/* Notify Type */
getevent_data->notifyType = AV_Descr[index].Notify_Type;
/* Event Enable */
bitstring_init(&getevent_data->eventEnable);
bitstring_set_bit(&getevent_data->eventEnable, TRANSITION_TO_OFFNORMAL,
(AV_Descr[index].Event_Enable & EVENT_ENABLE_TO_OFFNORMAL) ? true
: false);
bitstring_set_bit(&getevent_data->eventEnable, TRANSITION_TO_FAULT,
(AV_Descr[index].Event_Enable & EVENT_ENABLE_TO_FAULT) ? true
: false);
bitstring_set_bit(&getevent_data->eventEnable, TRANSITION_TO_NORMAL,
(AV_Descr[index].Event_Enable & EVENT_ENABLE_TO_NORMAL) ? true
: false);
/* Event Priorities */
Notification_Class_Get_Priorities(
AV_Descr[index].Notification_Class, getevent_data->eventPriorities);
return 1; /* active event */
} else
return 0; /* no active event at this index */
}
int Analog_Value_Alarm_Ack(
BACNET_ALARM_ACK_DATA *alarmack_data, BACNET_ERROR_CODE *error_code)
{
ANALOG_VALUE_DESCR *CurrentAV;
unsigned int object_index;
object_index = Analog_Value_Instance_To_Index(
alarmack_data->eventObjectIdentifier.instance);
if (object_index < MAX_ANALOG_VALUES)
CurrentAV = &AV_Descr[object_index];
else {
*error_code = ERROR_CODE_UNKNOWN_OBJECT;
return -1;
}
switch (alarmack_data->eventStateAcked) {
case EVENT_STATE_OFFNORMAL:
case EVENT_STATE_HIGH_LIMIT:
case EVENT_STATE_LOW_LIMIT:
if (CurrentAV->Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.bIsAcked == false) {
if (alarmack_data->eventTimeStamp.tag != TIME_STAMP_DATETIME) {
*error_code = ERROR_CODE_INVALID_TIME_STAMP;
return -1;
}
if (datetime_compare(
&CurrentAV->Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.Time_Stamp,
&alarmack_data->eventTimeStamp.value.dateTime) > 0) {
*error_code = ERROR_CODE_INVALID_TIME_STAMP;
return -1;
}
/* Clean transitions flag. */
CurrentAV->Acked_Transitions[TRANSITION_TO_OFFNORMAL].bIsAcked =
true;
} else if (alarmack_data->eventStateAcked ==
CurrentAV->Event_State) {
/* Send ack notification */
} else {
*error_code = ERROR_CODE_INVALID_EVENT_STATE;
return -1;
}
break;
case EVENT_STATE_FAULT:
if (CurrentAV->Acked_Transitions[TRANSITION_TO_NORMAL].bIsAcked ==
false) {
if (alarmack_data->eventTimeStamp.tag != TIME_STAMP_DATETIME) {
*error_code = ERROR_CODE_INVALID_TIME_STAMP;
return -1;
}
if (datetime_compare(
&CurrentAV->Acked_Transitions[TRANSITION_TO_NORMAL]
.Time_Stamp,
&alarmack_data->eventTimeStamp.value.dateTime) > 0) {
*error_code = ERROR_CODE_INVALID_TIME_STAMP;
return -1;
}
/* Clean transitions flag. */
CurrentAV->Acked_Transitions[TRANSITION_TO_FAULT].bIsAcked =
true;
} else if (alarmack_data->eventStateAcked ==
CurrentAV->Event_State) {
/* Send ack notification */
} else {
*error_code = ERROR_CODE_INVALID_EVENT_STATE;
return -1;
}
break;
case EVENT_STATE_NORMAL:
if (CurrentAV->Acked_Transitions[TRANSITION_TO_FAULT].bIsAcked ==
false) {
if (alarmack_data->eventTimeStamp.tag != TIME_STAMP_DATETIME) {
*error_code = ERROR_CODE_INVALID_TIME_STAMP;
return -1;
}
if (datetime_compare(
&CurrentAV->Acked_Transitions[TRANSITION_TO_FAULT]
.Time_Stamp,
&alarmack_data->eventTimeStamp.value.dateTime) > 0) {
*error_code = ERROR_CODE_INVALID_TIME_STAMP;
return -1;
}
/* Clean transitions flag. */
CurrentAV->Acked_Transitions[TRANSITION_TO_NORMAL].bIsAcked =
true;
} else if (alarmack_data->eventStateAcked ==
CurrentAV->Event_State) {
/* Send ack notification */
} else {
*error_code = ERROR_CODE_INVALID_EVENT_STATE;
return -1;
}
break;
default:
return -2;
}
/* Need to send AckNotification. */
CurrentAV->Ack_notify_data.bSendAckNotify = true;
CurrentAV->Ack_notify_data.EventState = alarmack_data->eventStateAcked;
/* Return OK */
return 1;
}
int Analog_Value_Alarm_Summary(
unsigned index, BACNET_GET_ALARM_SUMMARY_DATA *getalarm_data)
{
/* check index */
if (index < MAX_ANALOG_VALUES) {
/* Event_State is not equal to NORMAL and
Notify_Type property value is ALARM */
if ((AV_Descr[index].Event_State != EVENT_STATE_NORMAL) &&
(AV_Descr[index].Notify_Type == NOTIFY_ALARM)) {
/* Object Identifier */
getalarm_data->objectIdentifier.type = OBJECT_ANALOG_VALUE;
getalarm_data->objectIdentifier.instance =
Analog_Value_Index_To_Instance(index);
/* Alarm State */
getalarm_data->alarmState = AV_Descr[index].Event_State;
/* Acknowledged Transitions */
bitstring_init(&getalarm_data->acknowledgedTransitions);
bitstring_set_bit(&getalarm_data->acknowledgedTransitions,
TRANSITION_TO_OFFNORMAL,
AV_Descr[index]
.Acked_Transitions[TRANSITION_TO_OFFNORMAL]
.bIsAcked);
bitstring_set_bit(&getalarm_data->acknowledgedTransitions,
TRANSITION_TO_FAULT,
AV_Descr[index]
.Acked_Transitions[TRANSITION_TO_FAULT]
.bIsAcked);
bitstring_set_bit(&getalarm_data->acknowledgedTransitions,
TRANSITION_TO_NORMAL,
AV_Descr[index]
.Acked_Transitions[TRANSITION_TO_NORMAL]
.bIsAcked);
return 1; /* active alarm */
} else
return 0; /* no active alarm at this index */
} else
return -1; /* end of list */
}
#endif /* defined(INTRINSIC_REPORTING) */
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