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10 Commits
0.2.2 ... main

Author SHA1 Message Date
smathis
bc8561c299 Updated turboPmac version 2025-06-18 08:33:04 +02:00
smathis
cf6f836416 Updated turboPmac version 2025-06-17 16:51:08 +02:00
smathis
6e99b37ed2 Updated turboPmac version 2025-06-17 13:26:13 +02:00
smathis
f745af48fe Added destructor for detectorTowerController 2025-06-10 15:04:34 +02:00
smathis
0fd312b672 Updated dependency turboPmac to 1.1.1 2025-06-10 15:01:42 +02:00
smathis
c15e513b2e Updated turboPmac to 1.1.1 2025-06-10 15:00:33 +02:00
smathis
6f9b890374 Updated turboPmac to 1.1 2025-06-10 14:44:59 +02:00
smathis
fbbe8c4553 Updated turboPmac to 1.1 2025-06-10 14:22:15 +02:00
smathis
675819741b Updated turboPmac version 2025-06-10 13:57:57 +02:00
smathis
eb3826ec35 Stop or reset now also resets the deferred movement flags 2025-06-10 11:15:40 +02:00
9 changed files with 157 additions and 559 deletions
Expand all files Collapse all files

195
src/detectorTowerAngleAxis.cpp
View File

@ -1,5 +1,7 @@
#include "detectorTowerAngleAxis.h"
#include "detectorTowerController.h"
#include "detectorTowerLiftAxis.h"
#include "detectorTowerSupportAxis.h"
#include "turboPmacController.h"
#include <epicsExport.h>
#include <errlog.h>
@ -157,17 +159,8 @@ asynStatus detectorTowerAngleAxis::init() {
}
// Initialize the motorStatusMoving flag
status = setIntegerParam(pC_->motorStatusMoving(), 0);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusMoving_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
status = setIntegerParam(pC_->changeStateRBV(), positionState == 2);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "changeStateRBV", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(this, motorStatusMoving, false);
setAxisParamChecked(this, changeStateRBV, positionState == 2);
return callParamCallbacks();
}
@ -181,15 +174,9 @@ asynStatus detectorTowerAngleAxis::poll(bool *moving) {
if (axisNo() < liftAxis()->axisNo() && axisNo() < supportAxis()->axisNo()) {
status = pC_->pollDetectorAxes(moving, this, liftAxis(), supportAxis());
} else {
status = pC_->getIntegerParam(axisNo(), pC_->motorStatusMoving(),
(int *)moving);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusMoving",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
getAxisParamChecked(this, motorStatusMoving, moving);
}
}
wasMoving_ = *moving;
setWasMoving(*moving);
return status;
}
@ -206,17 +193,11 @@ asynStatus detectorTowerAngleAxis::doMove(double position, int relative,
double max_velocity,
double acceleration) {
double motorRecResolution = 0.0;
asynStatus plStatus = pC_->getDoubleParam(
axisNo_, pC_->motorRecResolution(), &motorRecResolution);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorRecResolution_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
getAxisParamChecked(this, motorRecResolution, &motorRecResolution);
// Signal to the deferredMovementCollectorLoop that a movement should be
// started to the defined target position.
targetPosition_ = position * motorRecResolution;
setTargetPosition(position * motorRecResolution);
receivedTarget_ = true;
return asynSuccess;
@ -225,10 +206,7 @@ asynStatus detectorTowerAngleAxis::doMove(double position, int relative,
asynStatus detectorTowerAngleAxis::startCombinedMove() {
// Status of read-write-operations of ASCII commands to the controller
asynStatus rwStatus = asynSuccess;
// Status of parameter library operations
asynStatus plStatus = asynSuccess;
asynStatus status = asynSuccess;
char command[pC_->MAXBUF_] = {0};
char response[pC_->MAXBUF_] = {0};
@ -237,12 +215,7 @@ asynStatus detectorTowerAngleAxis::startCombinedMove() {
// =========================================================================
plStatus =
pC_->getIntegerParam(axisNo_, pC_->positionStateRBV(), &positionState);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "positionStateRBV_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(this, positionStateRBV, &positionState);
// If the axis is in changer position, it must be moved into working
// position before any move can be started.
@ -259,20 +232,9 @@ asynStatus detectorTowerAngleAxis::startCombinedMove() {
pC_->getMsgPrintControl().getSuffix());
}
if (isInChangerPos) {
plStatus = setStringParam(pC_->motorMessageText(),
setAxisParamChecked(this, motorMessageText,
"Move the axis to working state first.");
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorMessageText",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
plStatus = setIntegerParam(pC_->motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, motorStatusProblem, true);
callParamCallbacks();
startingDeferredMovement_ = false;
@ -282,77 +244,64 @@ asynStatus detectorTowerAngleAxis::startCombinedMove() {
// Set the target positions for beam tilt, detector tilt offset and lift
// offset
snprintf(command, sizeof(command), "Q451=%lf Q454=%lf P350=1",
targetPosition_, liftAxis_->targetPosition_);
targetPosition(), liftAxis_->targetPosition());
// Lock the access to the controller since this function runs in another
// thread than the poll method.
pC_->lock();
// We don't expect an answer
rwStatus = pC_->writeRead(axisNo_, command, response, 0);
status = pC_->writeRead(axisNo_, command, response, 0);
// Free the controller again
pC_->unlock();
if (rwStatus != asynSuccess) {
if (status != asynSuccess) {
asynPrint(
pC_->pasynUser(), ASYN_TRACE_ERROR,
"Controller \"%s\", axis %d => %s, line %d\nStarting movement to "
"target position %lf failed.\n",
pC_->portName, axisNo_, __PRETTY_FUNCTION__, __LINE__,
motorCoordinatesPosition);
plStatus = setIntegerParam(pC_->motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, motorStatusProblem, true);
callParamCallbacks();
}
return rwStatus;
return status;
}
asynStatus detectorTowerAngleAxis::stop(double acceleration) {
// Status of read-write-operations of ASCII commands to the controller
asynStatus rwStatus = asynSuccess;
// Status of parameter library operations
asynStatus plStatus = asynSuccess;
asynStatus status = asynSuccess;
char response[pC_->MAXBUF_] = {0};
// =========================================================================
rwStatus = pC_->writeRead(axisNo_, "P350=8", response, 0);
status = pC_->writeRead(axisNo_, "P350=8", response, 0);
if (rwStatus != asynSuccess) {
if (status != asynSuccess) {
asynPrint(
pC_->pasynUser(), ASYN_TRACE_ERROR,
"Controller \"%s\", axis %d => %s, line %d\nStopping the movement "
"failed.\n",
pC_->portName, axisNo_, __PRETTY_FUNCTION__, __LINE__);
plStatus = setIntegerParam(pC_->motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, motorStatusProblem, true);
return asynError;
}
return rwStatus;
// Reset the deferred movement flags
startingDeferredMovement_ = false;
deferredMovementWait_ = false;
return status;
}
// The detector tower axis uses absolute encoders
asynStatus detectorTowerAngleAxis::readEncoderType() {
asynStatus status = setStringParam(pC_->encoderType(), AbsoluteEncoder);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "encoderType_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(this, encoderType, AbsoluteEncoder);
return asynSuccess;
}
@ -362,27 +311,19 @@ detectorTowerAngleAxis::toggleWorkingChangerState(bool toChangingPosition) {
char response[pC_->MAXBUF_] = {0};
// Status of read-write-operations of ASCII commands to the controller
asynStatus rwStatus = asynSuccess;
// Status of parameter library operations
asynStatus plStatus = asynSuccess;
asynStatus status = asynSuccess;
bool moving = false;
int positionState = 0;
// =========================================================================
rwStatus = poll(&moving);
if (rwStatus != asynSuccess) {
return rwStatus;
status = poll(&moving);
if (status != asynSuccess) {
return status;
}
plStatus =
pC_->getIntegerParam(axisNo_, pC_->positionStateRBV(), &positionState);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "positionStateRBV_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(this, positionStateRBV, &positionState);
if (moving) {
asynPrint(pC_->pasynUser(), ASYN_TRACE_ERROR,
@ -392,21 +333,10 @@ detectorTowerAngleAxis::toggleWorkingChangerState(bool toChangingPosition) {
toChangingPosition ? "changer" : "working",
pC_->getMsgPrintControl().getSuffix());
plStatus = setStringParam(
pC_->motorMessageText(),
setAxisParamChecked(
this, motorMessageText,
"Axis cannot be moved to changer position while it is moving.");
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorMessageText_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
plStatus = setIntegerParam(pC_->changeStateRBV(), !toChangingPosition);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "changeStateRBV",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, changeStateRBV, !toChangingPosition);
return asynError;
}
@ -424,39 +354,20 @@ detectorTowerAngleAxis::toggleWorkingChangerState(bool toChangingPosition) {
pC_->getMsgPrintControl().getSuffix());
// Update the PV anyway, even though nothing changed.
plStatus = setIntegerParam(pC_->changeStateRBV(), toChangingPosition);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "changeStateRBV",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, changeStateRBV, toChangingPosition);
return asynSuccess;
}
// Move the axis into changer or working position
if (toChangingPosition) {
rwStatus = pC_->writeRead(axisNo_, "P350=2", response, 0);
status = pC_->writeRead(axisNo_, "P350=2", response, 0);
} else {
rwStatus = pC_->writeRead(axisNo_, "P350=3", response, 0);
status = pC_->writeRead(axisNo_, "P350=3", response, 0);
}
if (plStatus != asynSuccess) {
plStatus = setIntegerParam(pC_->changeStateRBV(), !toChangingPosition);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "changeStateRBV",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
}
plStatus = setIntegerParam(pC_->changeStateRBV(), toChangingPosition);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "changeStateRBV", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
return rwStatus;
setAxisParamChecked(this, changeStateRBV, toChangingPosition);
return asynSuccess;
}
asynStatus detectorTowerAngleAxis::adjustOrigin(double newOrigin) {
@ -468,12 +379,7 @@ asynStatus detectorTowerAngleAxis::adjustOrigin(double newOrigin) {
// =========================================================================
status =
pC_->getIntegerParam(axisNo_, pC_->positionStateRBV(), &positionState);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "positionStateRBV_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(this, positionStateRBV, &positionState);
// If the axis is in changer position, it must be moved into working
// position before any move can be started.
@ -502,12 +408,7 @@ asynStatus detectorTowerAngleAxis::adjustOrigin(double newOrigin) {
"angle origin %lf failed.\n",
pC_->portName, axisNo_, __PRETTY_FUNCTION__, __LINE__,
newOrigin);
status = setIntegerParam(pC_->motorStatusProblem(), true);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, motorStatusProblem, true);
}
return status;
@ -516,15 +417,13 @@ asynStatus detectorTowerAngleAxis::adjustOrigin(double newOrigin) {
asynStatus detectorTowerAngleAxis::doReset() {
char response[pC_->MAXBUF_] = {0};
asynStatus plStatus = asynSuccess;
int positionState = 0;
plStatus =
pC_->getIntegerParam(axisNo_, pC_->positionStateRBV(), &positionState);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "positionStateRBV_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(this, positionStateRBV, &positionState);
// Reset the deferred movement flags
startingDeferredMovement_ = false;
deferredMovementWait_ = false;
/*
Check which action should be performed:

14
src/detectorTowerAngleAxis.h
View File

@ -1,14 +1,7 @@
#ifndef detectorTowerAngleAxis_H
#define detectorTowerAngleAxis_H
#include "detectorTowerController.h"
#include "turboPmacAxis.h"
#include <errlog.h>
// Forward declaration of the controller class to resolve the cyclic dependency
// between the controller and the axis .h-file. See
// https://en.cppreference.com/w/cpp/language/class.
class detectorTowerController;
class detectorTowerLiftAxis;
class detectorTowerSupportAxis;
class detectorTowerAngleAxis : public turboPmacAxis {
public:
@ -164,6 +157,11 @@ class detectorTowerAngleAxis : public turboPmacAxis {
*/
int error_;
/**
* @brief Return a pointer to the axis controller
*/
virtual detectorTowerController *pController() override { return pC_; };
protected:
detectorTowerController *pC_;
detectorTowerLiftAxis *liftAxis_;

328
src/detectorTowerController.cpp
View File

@ -1,6 +1,7 @@
#include "detectorTowerController.h"
#include "detectorTowerAngleAxis.h"
#include "turboPmacController.h"
#include "detectorTowerLiftAxis.h"
#include "detectorTowerSupportAxis.h"
#include <epicsExport.h>
#include <errlog.h>
#include <iocsh.h>
@ -106,11 +107,13 @@ detectorTowerController::detectorTowerController(
}
}
detectorTowerController::~detectorTowerController() {}
asynStatus detectorTowerController::readInt32(asynUser *pasynUser,
epicsInt32 *value) {
// The detector axes cannot be disabled
if (pasynUser->reason == motorCanDisable_) {
if (pasynUser->reason == motorCanDisable()) {
detectorTowerAngleAxis *aAxis = getDetectorTowerAngleAxis(pasynUser);
if (aAxis != nullptr) {
*value = 0;
@ -284,7 +287,7 @@ asynStatus detectorTowerController::pollDetectorAxes(
int error = 0;
int positionState = 0;
int inPosition = 0;
int notInPosition = 0;
double angle = 0.0;
double prevAngle = 0.0;
@ -334,37 +337,13 @@ asynStatus detectorTowerController::pollDetectorAxes(
The motorStatusProblem_ field changes the motor record fields SEVR and STAT.
*/
plStatus = angleAxis->setIntegerParam(motorStatusProblem(), false);
if (plStatus != asynSuccess) {
paramLibAccessFailed(plStatus, "motorStatusProblem_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(motorStatusProblem(), false);
if (plStatus != asynSuccess) {
paramLibAccessFailed(plStatus, "motorStatusProblem_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setIntegerParam(motorStatusProblem(), false);
if (plStatus != asynSuccess) {
paramLibAccessFailed(plStatus, "motorStatusProblem_", supportAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorStatusProblem, false);
setAxisParamChecked(liftAxis, motorStatusProblem, false);
setAxisParamChecked(supportAxis, motorStatusProblem, false);
plStatus = angleAxis->setIntegerParam(motorStatusCommsError(), false);
if (plStatus != asynSuccess) {
paramLibAccessFailed(plStatus, "motorStatusCommsError_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(motorStatusCommsError(), false);
if (plStatus != asynSuccess) {
paramLibAccessFailed(plStatus, "motorStatusCommsError_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setIntegerParam(motorStatusCommsError(), false);
if (plStatus != asynSuccess) {
paramLibAccessFailed(plStatus, "motorStatusCommsError_", supportAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorStatusCommsError, false);
setAxisParamChecked(liftAxis, motorStatusCommsError, false);
setAxisParamChecked(supportAxis, motorStatusCommsError, false);
// Read the previous motor positions
plStatus = angleAxis->motorPosition(&prevAngle);
@ -401,7 +380,7 @@ asynStatus detectorTowerController::pollDetectorAxes(
nvals =
sscanf(response,
"%d %d %d %lf %lf %lf %lf %lf %lf %lf %lf %lf %lf %lf %lf %lf",
&inPosition, &positionState, &error, &angle, &angleHighLimit,
&notInPosition, &positionState, &error, &angle, &angleHighLimit,
&angleLowLimit, &angleOrigin, &angleAdjustOriginHighLimit,
&angleAdjustOriginLowLimit, &lift, &liftHighLimit, &liftLowLimit,
&liftOrigin, &liftAdjustOriginHighLimit,
@ -425,20 +404,12 @@ asynStatus detectorTowerController::pollDetectorAxes(
*/
// Angle
plStatus = getDoubleParam(angleAxisNo, motorLimitsOffset(), &limitsOffset);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorLimitsOffset_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(angleAxis, motorLimitsOffset, &limitsOffset);
angleHighLimit = angleHighLimit - limitsOffset;
angleLowLimit = angleLowLimit + limitsOffset;
// Lift
plStatus = getDoubleParam(liftAxisNo, motorLimitsOffset(), &limitsOffset);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorLimitsOffset_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(liftAxis, motorLimitsOffset, &limitsOffset);
liftHighLimit = liftHighLimit - limitsOffset;
liftLowLimit = liftLowLimit + limitsOffset;
@ -446,7 +417,7 @@ asynStatus detectorTowerController::pollDetectorAxes(
angleAxis->error_ = error;
// Check if the tower is moving
if (inPosition == 1 || positionState > 2) {
if (notInPosition == 1 || positionState > 2) {
// By now, the controller has actually started the movement
angleAxis->startingDeferredMovement_ = false;
*moving = true;
@ -810,258 +781,84 @@ asynStatus detectorTowerController::pollDetectorAxes(
Does the paramLib already contain an error message? If either this is the
case or if error != 0, report a status problem for all axes.
*/
getStringParam(angleAxisNo, motorMessageText(), sizeof(waitingErrorMessage),
waitingErrorMessage);
getAxisParamChecked(angleAxis, motorMessageText, &waitingErrorMessage);
if (error != 0 || errorMessage[0] != '\0' ||
waitingErrorMessage[0] != '\0') {
plStatus = angleAxis->setIntegerParam(motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusProblem_",
angleAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
plStatus = liftAxis->setIntegerParam(motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusProblem_",
liftAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
plStatus = supportAxis->setIntegerParam(motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusProblem_",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(angleAxis, motorStatusProblem, true);
setAxisParamChecked(liftAxis, motorStatusProblem, true);
setAxisParamChecked(supportAxis, motorStatusProblem, true);
}
// Update the error message text with the one created in this poll (in case
// it is not empty).
if (errorMessage[0] != '\0') {
plStatus = angleAxis->setStringParam(motorMessageText(), errorMessage);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorMessageText_",
angleAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
plStatus = liftAxis->setStringParam(motorMessageText(), errorMessage);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorMessageText_",
liftAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
plStatus =
supportAxis->setStringParam(motorMessageText(), errorMessage);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorMessageText_",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(angleAxis, motorMessageText, errorMessage);
setAxisParamChecked(liftAxis, motorMessageText, errorMessage);
setAxisParamChecked(supportAxis, motorMessageText, errorMessage);
}
// Update the working position state PV
plStatus = angleAxis->setIntegerParam(positionStateRBV(), positionState);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "positionStateRBV_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(positionStateRBV(), positionState);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "positionStateRBV_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setIntegerParam(positionStateRBV(), positionState);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "positionStateRBV_",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(angleAxis, positionStateRBV, positionState);
setAxisParamChecked(liftAxis, positionStateRBV, positionState);
setAxisParamChecked(supportAxis, positionStateRBV, positionState);
// The axes are always enabled
plStatus = angleAxis->setIntegerParam(motorEnableRBV(), 1);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorEnableRBV_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(motorEnableRBV(), 1);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorEnableRBV_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setIntegerParam(motorEnableRBV(), 1);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorEnableRBV_", supportAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorEnableRBV, true);
setAxisParamChecked(liftAxis, motorEnableRBV, true);
setAxisParamChecked(supportAxis, motorEnableRBV, true);
// Are the axes currently moving?
plStatus = angleAxis->setIntegerParam(motorStatusMoving(), *moving);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusMoving_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(motorStatusMoving(), *moving);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusMoving_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setIntegerParam(motorStatusMoving(), *moving);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusMoving_",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(angleAxis, motorStatusMoving, *moving);
setAxisParamChecked(liftAxis, motorStatusMoving, *moving);
setAxisParamChecked(supportAxis, motorStatusMoving, *moving);
// Is the axis movement done?
plStatus = angleAxis->setIntegerParam(motorStatusDone(), !(*moving));
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusDone_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(motorStatusDone(), !(*moving));
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusDone_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setIntegerParam(motorStatusDone(), !(*moving));
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusDone_", supportAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorStatusDone, !(*moving));
setAxisParamChecked(liftAxis, motorStatusDone, !(*moving));
setAxisParamChecked(supportAxis, motorStatusDone, !(*moving));
// In which direction are the axes currently moving?
plStatus = angleAxis->setIntegerParam(motorStatusDirection(), angleDir);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusDirection_",
angleAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setIntegerParam(motorStatusDirection(), liftDir);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusDirection_",
liftAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorStatusDirection, angleDir);
setAxisParamChecked(liftAxis, motorStatusDirection, liftDir);
// Using the lift direction for the support axis is done on purpose!
plStatus = supportAxis->setIntegerParam(motorStatusDirection(), liftDir);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorStatusDirection_",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(supportAxis, motorStatusDirection, liftDir);
// High limits from hardware
plStatus =
setDoubleParam(angleAxisNo, motorHighLimitFromDriver(), angleHighLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorHighLimitFromDriver",
angleAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
plStatus =
setDoubleParam(liftAxisNo, motorHighLimitFromDriver(), liftHighLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorHighLimitFromDriver",
liftAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorHighLimitFromDriver, angleHighLimit);
setAxisParamChecked(liftAxis, motorHighLimitFromDriver, liftHighLimit);
// Using the lift high limit for the support axis is done on purpose!
plStatus = setDoubleParam(supportAxisNo, motorHighLimitFromDriver(),
liftHighLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorHighLimitFromDriver",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(supportAxis, motorHighLimitFromDriver, liftHighLimit);
// Low limits from hardware
plStatus =
setDoubleParam(angleAxisNo, motorLowLimitFromDriver(), angleLowLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorLowLimitFromDriver",
angleAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
plStatus =
setDoubleParam(liftAxisNo, motorLowLimitFromDriver(), liftLowLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorLowLimitFromDriver",
liftAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorLowLimitFromDriver, angleLowLimit);
setAxisParamChecked(liftAxis, motorLowLimitFromDriver, liftLowLimit);
// Using the lift low limit for the support axis is done on purpose!
plStatus =
setDoubleParam(supportAxisNo, motorLowLimitFromDriver(), liftLowLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorLowLimitFromDriver",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(supportAxis, motorLowLimitFromDriver, liftLowLimit);
// Write the motor origin
plStatus = setDoubleParam(angleAxisNo, motorOrigin(), angleOrigin);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorOrigin", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = setDoubleParam(liftAxisNo, motorOrigin(), liftOrigin);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorOrigin", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = setDoubleParam(supportAxisNo, motorOrigin(), supportOrigin);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "supportOrigin", supportAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(angleAxis, motorOrigin, angleOrigin);
setAxisParamChecked(liftAxis, motorOrigin, liftOrigin);
setAxisParamChecked(supportAxis, motorOrigin, supportOrigin);
// Origin adjustment high limit
plStatus =
setDoubleParam(angleAxisNo, motorAdjustOriginHighLimitFromDriver(),
setAxisParamChecked(angleAxis, motorAdjustOriginHighLimitFromDriver,
angleAdjustOriginHighLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorOriginHighLimitFromDriver",
angleAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
plStatus =
setDoubleParam(liftAxisNo, motorAdjustOriginHighLimitFromDriver(),
setAxisParamChecked(liftAxis, motorAdjustOriginHighLimitFromDriver,
liftAdjustOriginHighLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorOriginHighLimitFromDriver",
liftAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
// Using the lift high limit for the support axis is done on purpose!
plStatus =
setDoubleParam(supportAxisNo, motorAdjustOriginHighLimitFromDriver(),
setAxisParamChecked(supportAxis, motorAdjustOriginHighLimitFromDriver,
liftAdjustOriginHighLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorOriginHighLimitFromDriver",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
// Origin adjustment low limit
plStatus =
setDoubleParam(angleAxisNo, motorAdjustOriginLowLimitFromDriver(),
setAxisParamChecked(angleAxis, motorAdjustOriginLowLimitFromDriver,
angleAdjustOriginLowLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus,
"motorAdjustOriginLowLimitFromDriver",
angleAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
plStatus = setDoubleParam(liftAxisNo, motorAdjustOriginLowLimitFromDriver(),
setAxisParamChecked(liftAxis, motorAdjustOriginLowLimitFromDriver,
liftAdjustOriginLowLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus,
"motorAdjustOriginLowLimitFromDriver",
liftAxisNo, __PRETTY_FUNCTION__, __LINE__);
}
// Using the lift low limit for the support axis is done on purpose!
plStatus =
setDoubleParam(supportAxisNo, motorAdjustOriginLowLimitFromDriver(),
setAxisParamChecked(supportAxis, motorAdjustOriginLowLimitFromDriver,
liftAdjustOriginLowLimit);
if (plStatus != asynSuccess) {
return paramLibAccessFailed(
plStatus, "motorAdjustOriginLowLimitFromDriver", supportAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
// Axes positions
plStatus = angleAxis->setMotorPosition(angle);
@ -1135,22 +932,9 @@ asynStatus detectorTowerController::pollDetectorAxes(
one poll cycle, but are cleared afterwards. Persisting error messages will
be recreated during each poll.
*/
plStatus = angleAxis->setStringParam(motorMessageText(), "");
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorMessageText_", angleAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = liftAxis->setStringParam(motorMessageText(), "");
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorMessageText_", liftAxisNo,
__PRETTY_FUNCTION__, __LINE__);
}
plStatus = supportAxis->setStringParam(motorMessageText(), "");
if (plStatus != asynSuccess) {
return paramLibAccessFailed(plStatus, "motorMessageText_",
supportAxisNo, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(angleAxis, motorMessageText, "");
setAxisParamChecked(liftAxis, motorMessageText, "");
setAxisParamChecked(supportAxis, motorMessageText, "");
return pollStatus;
}

12
src/detectorTowerController.h
View File

@ -8,11 +8,15 @@
#ifndef detectorTowerController_H
#define detectorTowerController_H
#include "detectorTowerAngleAxis.h"
#include "detectorTowerLiftAxis.h"
#include "detectorTowerSupportAxis.h"
#include "turboPmacController.h"
// Forward declaration of the axis classes to resolve the cyclic dependency
// between the controller and the axis .h-file. See
// https://en.cppreference.com/w/cpp/language/class.
class detectorTowerAngleAxis;
class detectorTowerLiftAxis;
class detectorTowerSupportAxis;
class detectorTowerController : public turboPmacController {
public:
@ -35,6 +39,8 @@ class detectorTowerController : public turboPmacController {
int numAxes, double movingPollPeriod,
double idlePollPeriod, double comTimeout);
virtual ~detectorTowerController();
/**
* @brief Overloaded function of turboPmacController
*

80
src/detectorTowerLiftAxis.cpp
View File

@ -1,6 +1,7 @@
#include "detectorTowerLiftAxis.h"
#include "detectorTowerAngleAxis.h"
#include "detectorTowerController.h"
#include "detectorTowerSupportAxis.h"
#include "turboPmacController.h"
#include <epicsExport.h>
#include <errlog.h>
@ -111,11 +112,7 @@ asynStatus detectorTowerLiftAxis::init() {
}
// Initialize the motorStatusMoving flag
status = setIntegerParam(pC_->motorStatusMoving(), 0);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusMoving_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(this, motorStatusMoving, false);
// Check if we are currently in the changer position and update the PV
// accordingly
@ -126,11 +123,7 @@ asynStatus detectorTowerLiftAxis::init() {
__PRETTY_FUNCTION__, __LINE__);
}
status = setIntegerParam(pC_->changeStateRBV(), positionState == 2);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "changeStateRBV", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(this, changeStateRBV, positionState == 2);
return callParamCallbacks();
}
@ -146,15 +139,9 @@ asynStatus detectorTowerLiftAxis::poll(bool *moving) {
status = pC_->pollDetectorAxes(moving, angleAxis(), this,
angleAxis()->supportAxis());
} else {
status = pC_->getIntegerParam(axisNo(), pC_->motorStatusMoving(),
(int *)moving);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusMoving",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
getAxisParamChecked(this, motorStatusMoving, moving);
}
}
wasMoving_ = *moving;
setWasMoving(*moving);
return status;
}
@ -172,18 +159,12 @@ asynStatus detectorTowerLiftAxis::doMove(double position, int relative,
double acceleration) {
double motorRecResolution = 0.0;
asynStatus plStatus = pC_->getDoubleParam(
axisNo_, pC_->motorRecResolution(), &motorRecResolution);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorRecResolution_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
getAxisParamChecked(this, motorRecResolution, &motorRecResolution);
// Signal to the deferredMovementCollectorLoop (of the
// detectorTowerAngleAxis) that a movement should be started to the
// defined target position.
targetPosition_ = position * motorRecResolution;
setTargetPosition(position * motorRecResolution);
angleAxis_->receivedTarget_ = true;
return asynSuccess;
@ -192,37 +173,8 @@ asynStatus detectorTowerLiftAxis::doMove(double position, int relative,
asynStatus detectorTowerLiftAxis::reset() { return angleAxis()->reset(); };
asynStatus detectorTowerLiftAxis::stop(double acceleration) {
// Status of read-write-operations of ASCII commands to the controller
asynStatus rwStatus = asynSuccess;
// Status of parameter library operations
asynStatus plStatus = asynSuccess;
char response[pC_->MAXBUF_] = {0};
// =========================================================================
rwStatus = pC_->writeRead(axisNo_, "P350=8", response, 0);
if (rwStatus != asynSuccess) {
asynPrint(pC_->pasynUser(), ASYN_TRACE_ERROR,
"Controller \"%s\", axis %d => %s, line %d\nStopping "
"the movement "
"failed.\n",
pC_->portName, axisNo_, __PRETTY_FUNCTION__, __LINE__);
plStatus = setIntegerParam(pC_->motorStatusProblem(), true);
if (plStatus != asynSuccess) {
return pC_->paramLibAccessFailed(plStatus, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
return asynError;
}
return rwStatus;
}
return angleAxis()->stop(acceleration);
};
asynStatus detectorTowerLiftAxis::readEncoderType() {
return angleAxis()->readEncoderType();
@ -237,12 +189,7 @@ asynStatus detectorTowerLiftAxis::adjustOrigin(double newOrigin) {
// =========================================================================
status =
pC_->getIntegerParam(axisNo_, pC_->positionStateRBV(), &positionState);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "positionStateRBV_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(this, positionStateRBV, &positionState);
// If the axis is in changer position, it must be moved into working
// position before any move can be started.
@ -271,12 +218,7 @@ asynStatus detectorTowerLiftAxis::adjustOrigin(double newOrigin) {
"lift origin %lf failed.\n",
pC_->portName, axisNo_, __PRETTY_FUNCTION__, __LINE__,
newOrigin);
status = setIntegerParam(pC_->motorStatusProblem(), true);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, motorStatusProblem, true);
}
return status;

16
src/detectorTowerLiftAxis.h
View File

@ -1,13 +1,8 @@
#ifndef detectorTowerLiftAxis_H
#define detectorTowerLiftAxis_H
#include "detectorTowerController.h"
#include "turboPmacAxis.h"
// Forward declaration of the controller class to resolve the cyclic dependency
// between the controller and the axis .h-file. See
// https://en.cppreference.com/w/cpp/language/class.
class detectorTowerController;
class detectorTowerAngleAxis;
class detectorTowerLiftAxis : public turboPmacAxis {
public:
/**
@ -19,10 +14,6 @@ class detectorTowerLiftAxis : public turboPmacAxis {
detectorTowerLiftAxis(detectorTowerController *pController, int axisNo,
detectorTowerAngleAxis *angleAxis);
/**
* @brief Destroy the turboPmacAxis
*
*/
virtual ~detectorTowerLiftAxis();
/**
@ -114,6 +105,11 @@ class detectorTowerLiftAxis : public turboPmacAxis {
*/
asynStatus readEncoderType();
/**
* @brief Return a pointer to the axis controller
*/
virtual detectorTowerController *pController() override { return pC_; };
protected:
detectorTowerController *pC_;
detectorTowerAngleAxis *angleAxis_;

39
src/detectorTowerSupportAxis.cpp
View File

@ -1,6 +1,7 @@
#include "detectorTowerSupportAxis.h"
#include "detectorTowerAngleAxis.h"
#include "detectorTowerController.h"
#include "detectorTowerLiftAxis.h"
#include "turboPmacController.h"
#include <epicsExport.h>
#include <errlog.h>
@ -111,11 +112,7 @@ asynStatus detectorTowerSupportAxis::init() {
}
// Initialize the motorStatusMoving flag
status = setIntegerParam(pC_->motorStatusMoving(), 0);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusMoving_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(this, motorStatusMoving, false);
// Check if we are currently in the changer position and update the PV
// accordingly
@ -126,12 +123,7 @@ asynStatus detectorTowerSupportAxis::init() {
__PRETTY_FUNCTION__, __LINE__);
}
status = setIntegerParam(pC_->changeStateRBV(), positionState == 2);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "changeStateRBV", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
setAxisParamChecked(this, changeStateRBV, positionState == 2);
return callParamCallbacks();
}
@ -147,15 +139,9 @@ asynStatus detectorTowerSupportAxis::poll(bool *moving) {
status = pC_->pollDetectorAxes(moving, angleAxis(),
angleAxis()->liftAxis(), this);
} else {
status = pC_->getIntegerParam(axisNo(), pC_->motorStatusMoving(),
(int *)moving);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusMoving",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
getAxisParamChecked(this, motorStatusMoving, moving);
}
}
wasMoving_ = *moving;
setWasMoving(*moving);
return status;
}
@ -186,12 +172,7 @@ asynStatus detectorTowerSupportAxis::adjustOrigin(double newOrigin) {
// =========================================================================
status =
pC_->getIntegerParam(axisNo_, pC_->positionStateRBV(), &positionState);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "positionStateRBV_", axisNo_,
__PRETTY_FUNCTION__, __LINE__);
}
getAxisParamChecked(this, positionStateRBV, &positionState);
// If the axis is in changer position, it must be moved into working
// position before any move can be started.
@ -220,12 +201,8 @@ asynStatus detectorTowerSupportAxis::adjustOrigin(double newOrigin) {
"lift origin %lf failed.\n",
pC_->portName, axisNo_, __PRETTY_FUNCTION__, __LINE__,
newOrigin);
status = setIntegerParam(pC_->motorStatusProblem(), true);
if (status != asynSuccess) {
return pC_->paramLibAccessFailed(status, "motorStatusProblem_",
axisNo_, __PRETTY_FUNCTION__,
__LINE__);
}
setAxisParamChecked(this, motorStatusProblem, true);
}
return status;

16
src/detectorTowerSupportAxis.h
View File

@ -1,13 +1,8 @@
#ifndef detectorTowerSupportAxis_H
#define detectorTowerSupportAxis_H
#include "detectorTowerController.h"
#include "turboPmacAxis.h"
// Forward declaration of the controller class to resolve the cyclic dependency
// between the controller and the axis .h-file. See
// https://en.cppreference.com/w/cpp/language/class.
class detectorTowerController;
class detectorTowerAngleAxis;
/**
* @brief Passive axis which is mostly controlled indirectly by the hardware
*
@ -24,10 +19,6 @@ class detectorTowerSupportAxis : public turboPmacAxis {
detectorTowerSupportAxis(detectorTowerController *pController, int axisNo,
detectorTowerAngleAxis *angleAxis);
/**
* @brief Destroy the detectorTowerSupportAxis
*
*/
virtual ~detectorTowerSupportAxis();
/**
@ -116,6 +107,11 @@ class detectorTowerSupportAxis : public turboPmacAxis {
*/
asynStatus readEncoderType();
/**
* @brief Return a pointer to the axis controller
*/
virtual detectorTowerController *pController() override { return pC_; };
protected:
detectorTowerController *pC_;
detectorTowerAngleAxis *angleAxis_;

2
turboPmac

Submodule turboPmac updated: a11d10cb6c...f423002d23