Add "Generate Program" to toolbar in PLCOpenEditor standalone mode.
Currently you can find the "Generate Program" action only in the file menu,
but this action is very often used in standalone mode, so I added toolbuffon.
/*
Template C code used to produce target Ethercat C CIA402 code
Copyright (C) 2011-2014: Laurent BESSARD, Edouard TISSERANT
Distributed under the terms of the GNU Lesser General Public License as
published by the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
See COPYING file for copyrights details.
*/
#include "ecrt.h"
#include "beremiz.h"
#include "iec_types_all.h"
#include "accessor.h"
#include "POUS.h"
/* From CiA402, page 27
Table 30 - State coding
Statusword | PDS FSA state
xxxx xxxx x0xx 0000 | Not ready to switch on
xxxx xxxx x1xx 0000 | Switch on disabled
xxxx xxxx x01x 0001 | Ready to switch on
xxxx xxxx x01x 0011 | Switched on
xxxx xxxx x01x 0111 | Operation enabled
xxxx xxxx x00x 0111 | Quick stop active
xxxx xxxx x0xx 1111 | Fault reaction active
xxxx xxxx x0xx 1000 | Fault
*/
#define FSAFromStatusWord(SW) (SW & 0x006f)
#define NotReadyToSwitchOn 0b00000000 FSA_sep 0b00100000
#define SwitchOnDisabled 0b01000000 FSA_sep 0b01100000
#define ReadyToSwitchOn 0b00100001
#define SwitchedOn 0b00100011
#define OperationEnabled 0b00100111
#define QuickStopActive 0b00000111
#define FaultReactionActive 0b00001111 FSA_sep 0b00101111
#define Fault 0b00001000 FSA_sep 0b00101000
// SatusWord bits :
#define SW_ReadyToSwitchOn 0x0001
#define SW_SwitchedOn 0x0002
#define SW_OperationEnabled 0x0004
#define SW_Fault 0x0008
#define SW_VoltageEnabled 0x0010
#define SW_QuickStop 0x0020
#define SW_SwitchOnDisabled 0x0040
#define SW_Warning 0x0080
#define SW_Remote 0x0200
#define SW_TargetReached 0x0400
#define SW_InternalLimitActive 0x0800
// ControlWord bits :
#define SwitchOn 0x0001
#define EnableVoltage 0x0002
#define QuickStop 0x0004
#define EnableOperation 0x0008
#define FaultReset 0x0080
#define Halt 0x0100
IEC_INT beremiz__IW%(location_str)s = %(slave_pos)s;
IEC_INT *__IW%(location_str)s = &beremiz__IW%(location_str)s;
IEC_INT beremiz__IW%(location_str)s_402;
IEC_INT *__IW%(location_str)s_402 = &beremiz__IW%(location_str)s_402;
%(MCL_headers)s
static IEC_BOOL __FirstTick = 1;
typedef enum {
mc_mode_none, // No motion mode
mc_mode_csp, // Continuous Synchronous Positionning mode
mc_mode_csv, // Continuous Synchronous Velocity mode
mc_mode_cst, // Continuous Synchronous Torque mode
} mc_axismotionmode_enum;
typedef struct {
IEC_BOOL Power;
IEC_BOOL CommunicationReady;
IEC_UINT NetworkPosition;
IEC_BOOL ReadyForPowerOn;
IEC_BOOL PowerFeedback;
IEC_DINT ActualRawPosition;
IEC_DINT ActualRawVelocity;
IEC_DINT ActualRawTorque;
IEC_DINT RawPositionSetPoint;
IEC_DINT RawVelocitySetPoint;
IEC_DINT RawTorqueSetPoint;
mc_axismotionmode_enum AxisMotionMode;
IEC_LREAL ActualVelocity;
IEC_LREAL ActualPosition;
IEC_LREAL ActualTorque;
}axis_s;
typedef struct {
%(entry_variables)s
axis_s* axis;
} __CIA402Node;
#define AxsPub __CIA402Node_%(location_str)s
static __CIA402Node AxsPub;
%(extern_located_variables_declaration)s
%(fieldbus_interface_declaration)s
int __init_%(location_str)s()
{
__FirstTick = 1;
%(init_entry_variables)s
*(AxsPub.ModesOfOperation) = 0x08;
return 0;
}
void __cleanup_%(location_str)s()
{
}
void __retrieve_%(location_str)s()
{
if (__FirstTick) {
*__IW%(location_str)s_402 = __MK_Alloc_AXIS_REF();
AxsPub.axis =
__MK_GetPublic_AXIS_REF(*__IW%(location_str)s_402);
AxsPub.axis->NetworkPosition = beremiz__IW%(location_str)s;
%(init_axis_params)s
%(fieldbus_interface_definition)s
__FirstTick = 0;
}
// Default variables retrieve
AxsPub.axis->CommunicationReady =
*(AxsPub.StatusWord) != 0;
#define FSA_sep || FSA ==
{
uint16_t FSA = FSAFromStatusWord(*(AxsPub.StatusWord));
AxsPub.axis->ReadyForPowerOn = FSA == ReadyToSwitchOn;
AxsPub.axis->PowerFeedback = FSA == OperationEnabled;
}
#undef FSA_sep
AxsPub.axis->ActualRawPosition = *(AxsPub.ActualPosition);
AxsPub.axis->ActualRawVelocity = *(AxsPub.ActualVelocity);
AxsPub.axis->ActualRawTorque = *(AxsPub.ActualTorque);
// Extra variables retrieve
%(extra_variables_retrieve)s
}
void __publish_%(location_str)s()
{
IEC_BOOL power =
((*(AxsPub.StatusWord) & SW_VoltageEnabled) != 0)
&& AxsPub.axis->Power;
uint16_t CW = *(AxsPub.ControlWord);
#define FSA_sep : case
// CIA402 node state transition computation
switch (FSAFromStatusWord(*(AxsPub.StatusWord))) {
case SwitchOnDisabled :
CW &= ~(SwitchOn | FaultReset);
CW |= EnableVoltage | QuickStop;
break;
case ReadyToSwitchOn :
case OperationEnabled :
if (!power) {
CW &= ~(FaultReset | EnableOperation);
CW |= SwitchOn | EnableVoltage | QuickStop;
break;
}
case SwitchedOn :
if (power) {
CW &= ~(FaultReset);
CW |= SwitchOn | EnableVoltage | QuickStop | EnableOperation;
}
break;
case Fault :
/* TODO reset fault only when MC_Reset */
CW &= ~(SwitchOn | EnableVoltage | QuickStop | EnableOperation);
CW |= FaultReset;
break;
default:
break;
}
#undef FSA_sep
*(AxsPub.ControlWord) = CW;
// CIA402 node modes of operation computation according to axis motion mode
switch (AxsPub.axis->AxisMotionMode) {
case mc_mode_cst:
*(AxsPub.ModesOfOperation) = 0x0a;
break;
case mc_mode_csv:
*(AxsPub.ModesOfOperation) = 0x09;
break;
default:
*(AxsPub.ModesOfOperation) = 0x08;
break;
}
// Default variables publish
*(AxsPub.TargetPosition) =
AxsPub.axis->RawPositionSetPoint;
*(AxsPub.TargetVelocity) =
AxsPub.axis->RawVelocitySetPoint;
*(AxsPub.TargetTorque) =
AxsPub.axis->RawTorqueSetPoint;
// Extra variables publish
%(extra_variables_publish)s
}