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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / 1a67511767f0d422c346bbe181debaf7bd9e03a9 / . / hal / lib / Athena / ctre / CanTalonSRX.cpp
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/**
* @brief CAN TALON SRX driver.
*
* The TALON SRX is designed to instrument all runtime signals periodically.
* The default periods are chosen to support 16 TALONs with 10ms update rate
* for control (throttle or setpoint). However these can be overridden with
* SetStatusFrameRate. @see SetStatusFrameRate
* The getters for these unsolicited signals are auto generated at the bottom
* of this module.
*
* Likewise most control signals are sent periodically using the fire-and-forget
* CAN API. The setters for these unsolicited signals are auto generated at the
* bottom of this module.
*
* Signals that are not available in an unsolicited fashion are the Close Loop
* gains. For teams that have a single profile for their TALON close loop they
* can use either the webpage to configure their TALONs once or set the PIDF,
* Izone, CloseLoopRampRate, etc... once in the robot application. These
* parameters are saved to flash so once they are loaded in the TALON, they
* will persist through power cycles and mode changes.
*
* For teams that have one or two profiles to switch between, they can use the
* same strategy since there are two slots to choose from and the
* ProfileSlotSelect is periodically sent in the 10 ms control frame.
*
* For teams that require changing gains frequently, they can use the soliciting
* API to get and set those parameters. Most likely they will only need to set
* them in a periodic fashion as a function of what motion the application is
* attempting. If this API is used, be mindful of the CAN utilization reported
* in the driver station.
*
* If calling application has used the config routines to configure the
* selected feedback sensor, then all positions are measured in floating point
* precision rotations. All sensor velocities are specified in floating point
* precision RPM.
* @see ConfigPotentiometerTurns
* @see ConfigEncoderCodesPerRev
* HOWEVER, if calling application has not called the config routine for
* selected feedback sensor, then all getters/setters for position/velocity use
* the native engineering units of the Talon SRX firm (just like in 2015).
* Signals explained below.
*
* Encoder position is measured in encoder edges. Every edge is counted
* (similar to roboRIO 4X mode). Analog position is 10 bits, meaning 1024
* ticks per rotation (0V => 3.3V). Use SetFeedbackDeviceSelect to select
* which sensor type you need. Once you do that you can use GetSensorPosition()
* and GetSensorVelocity(). These signals are updated on CANBus every 20ms (by
* default). If a relative sensor is selected, you can zero (or change the
* current value) using SetSensorPosition.
*
* Analog Input and quadrature position (and velocity) are also explicitly
* reported in GetEncPosition, GetEncVel, GetAnalogInWithOv, GetAnalogInVel.
* These signals are available all the time, regardless of what sensor is
* selected at a rate of 100ms. This allows easy instrumentation for "in the
* pits" checking of all sensors regardless of modeselect. The 100ms rate is
* overridable for teams who want to acquire sensor data for processing, not
* just instrumentation. Or just select the sensor using
* SetFeedbackDeviceSelect to get it at 20ms.
*
* Velocity is in position ticks / 100ms.
*
* All output units are in respect to duty cycle (throttle) which is -1023(full
* reverse) to +1023 (full forward). This includes demand (which specifies
* duty cycle when in duty cycle mode) and rampRamp, which is in throttle units
* per 10ms (if nonzero).
*
* Pos and velocity close loops are calc'd as
* err = target - posOrVel.
* iErr += err;
* if( (IZone!=0) and abs(err) > IZone)
* ClearIaccum()
* output = P X err + I X iErr + D X dErr + F X target
* dErr = err - lastErr
* P, I, and D gains are always positive. F can be negative.
* Motor direction can be reversed using SetRevMotDuringCloseLoopEn if
* sensor and motor are out of phase. Similarly feedback sensor can also be
* reversed (multiplied by -1) if you prefer the sensor to be inverted.
*
* P gain is specified in throttle per error tick. For example, a value of 102
* is ~9.9% (which is 102/1023) throttle per 1 ADC unit(10bit) or 1 quadrature
* encoder edge depending on selected sensor.
*
* I gain is specified in throttle per integrated error. For example, a value
* of 10 equates to ~0.99% (which is 10/1023) for each accumulated ADC unit
* (10 bit) or 1 quadrature encoder edge depending on selected sensor.
* Close loop and integral accumulator runs every 1ms.
*
* D gain is specified in throttle per derivative error. For example a value of
* 102 equates to ~9.9% (which is 102/1023) per change of 1 unit (ADC or
* encoder) per ms.
*
* I Zone is specified in the same units as sensor position (ADC units or
* quadrature edges). If pos/vel error is outside of this value, the
* integrated error will auto-clear...
* if( (IZone!=0) and abs(err) > IZone)
* ClearIaccum()
* ...this is very useful in preventing integral windup and is highly
* recommended if using full PID to keep stability low.
*
* CloseLoopRampRate is in throttle units per 1ms. Set to zero to disable
* ramping. Works the same as RampThrottle but only is in effect when a close
* loop mode and profile slot is selected.
*
* auto generated using spreadsheet and wpiclassgen.py
* @link https://docs.google.com/spreadsheets/d/1OU_ZV7fZLGYUQ-Uhc8sVAmUmWTlT8XBFYK8lfjg_tac/edit#gid=1766046967
*/
#include "HAL/CanTalonSRX.h"
#include "FRC_NetworkCommunication/CANSessionMux.h" //CAN Comm
#include <string.h> // memset
#include <unistd.h> // usleep
#define STATUS_1 0x02041400
#define STATUS_2 0x02041440
#define STATUS_3 0x02041480
#define STATUS_4 0x020414C0
#define STATUS_5 0x02041500
#define STATUS_6 0x02041540
#define STATUS_7 0x02041580
#define STATUS_8 0x020415C0
#define STATUS_9 0x02041600
#define CONTROL_1 0x02040000
#define CONTROL_2 0x02040040
#define CONTROL_3 0x02040080
#define CONTROL_5 0x02040100
#define CONTROL_6 0x02040140
#define EXPECTED_RESPONSE_TIMEOUT_MS (200)
#define GET_STATUS1() \
CtreCanNode::recMsg<TALON_Status_1_General_10ms_t> rx = \
GetRx<TALON_Status_1_General_10ms_t>(STATUS_1 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS2() \
CtreCanNode::recMsg<TALON_Status_2_Feedback_20ms_t> rx = \
GetRx<TALON_Status_2_Feedback_20ms_t>(STATUS_2 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS3() \
CtreCanNode::recMsg<TALON_Status_3_Enc_100ms_t> rx = \
GetRx<TALON_Status_3_Enc_100ms_t>(STATUS_3 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS4() \
CtreCanNode::recMsg<TALON_Status_4_AinTempVbat_100ms_t> rx = \
GetRx<TALON_Status_4_AinTempVbat_100ms_t>(STATUS_4 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS5() \
CtreCanNode::recMsg<TALON_Status_5_Startup_OneShot_t> rx = \
GetRx<TALON_Status_5_Startup_OneShot_t>(STATUS_5 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS6() \
CtreCanNode::recMsg<TALON_Status_6_Eol_t> rx = GetRx<TALON_Status_6_Eol_t>( \
STATUS_6 | GetDeviceNumber(), EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS7() \
CtreCanNode::recMsg<TALON_Status_7_Debug_200ms_t> rx = \
GetRx<TALON_Status_7_Debug_200ms_t>(STATUS_7 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS8() \
CtreCanNode::recMsg<TALON_Status_8_PulseWid_100ms_t> rx = \
GetRx<TALON_Status_8_PulseWid_100ms_t>(STATUS_8 | GetDeviceNumber(), \
EXPECTED_RESPONSE_TIMEOUT_MS)
#define GET_STATUS9() \
CtreCanNode::recMsg<TALON_Status_9_MotProfBuffer_100ms_t> rx = \
GetRx<TALON_Status_9_MotProfBuffer_100ms_t>( \
STATUS_9 | GetDeviceNumber(), EXPECTED_RESPONSE_TIMEOUT_MS)
#define PARAM_REQUEST 0x02041800
#define PARAM_RESPONSE 0x02041840
#define PARAM_SET 0x02041880
const int kParamArbIdValue = PARAM_RESPONSE;
const int kParamArbIdMask = 0xFFFFFFFF;
const double FLOAT_TO_FXP_10_22 = (double)0x400000;
const double FXP_TO_FLOAT_10_22 = 0.0000002384185791015625;
const double FLOAT_TO_FXP_0_8 = (double)0x100;
const double FXP_TO_FLOAT_0_8 = 0.00390625;
CanTalonSRX::CanTalonSRX(int deviceNumber, int controlPeriodMs,
int enablePeriodMs)
: CtreCanNode(deviceNumber), _can_h(0), _can_stat(0) {
_controlPeriodMs = controlPeriodMs;
_enablePeriodMs = enablePeriodMs;
/* bound period to be within [1 ms,95 ms] */
if (_controlPeriodMs < 1)
_controlPeriodMs = 1;
else if (_controlPeriodMs > 95)
_controlPeriodMs = 95;
if (_enablePeriodMs < 1)
_enablePeriodMs = 1;
else if (_enablePeriodMs > 95)
_enablePeriodMs = 95;
RegisterRx(STATUS_1 | (UINT8)deviceNumber);
RegisterRx(STATUS_2 | (UINT8)deviceNumber);
RegisterRx(STATUS_3 | (UINT8)deviceNumber);
RegisterRx(STATUS_4 | (UINT8)deviceNumber);
RegisterRx(STATUS_5 | (UINT8)deviceNumber);
RegisterRx(STATUS_6 | (UINT8)deviceNumber);
RegisterRx(STATUS_7 | (UINT8)deviceNumber);
/* use the legacy command frame until we have evidence we can use the new
* frame.
*/
RegisterTx(CONTROL_1 | (UINT8)deviceNumber, (UINT8)_controlPeriodMs);
_controlFrameArbId = CONTROL_1;
/* the only default param that is nonzero is limit switch.
* Default to using the flash settings.
*/
SetOverrideLimitSwitchEn(kLimitSwitchOverride_UseDefaultsFromFlash);
/* Check if we can upgrade the control framing */
UpdateControlId();
}
/* CanTalonSRX D'tor
*/
CanTalonSRX::~CanTalonSRX() {
if (m_hasBeenMoved) {
/* Another CANTalonSRX still exists, so don't un-register the periodic
* control frame
*/
} else {
/* un-register the control frame so Talon is disabled */
RegisterTx(CONTROL_1 | (UINT8)GetDeviceNumber(), 0);
RegisterTx(CONTROL_5 | (UINT8)GetDeviceNumber(), 0);
}
/* free the stream we used for SetParam/GetParamResponse */
if (_can_h) {
FRC_NetworkCommunication_CANSessionMux_closeStreamSession(_can_h);
_can_h = 0;
}
}
/**
* @return true if Talon is reporting that it supports control5, and therefore
* RIO can send control5 to update control params (even when disabled).
*/
bool CanTalonSRX::IsControl5Supported() {
/* only bother to poll status2 if we are looking for cmd5allowed */
GET_STATUS2();
if (rx.err != CTR_OKAY) {
/* haven't received it */
return false;
} else if (0 == rx->Cmd5Allowed) {
/* firmware doesn't support it */
return false;
}
/* we can use control5, this gives application the ability to set control
* params prior to Talon-enable */
return true;
}
/**
* Get a copy of the control frame to send.
* @param [out] pointer to eight byte array to fill.
*/
void CanTalonSRX::GetControlFrameCopy(uint8_t *toFill) {
/* get the copy of the control frame in control1 */
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> task =
GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId |
GetDeviceNumber());
/* control1's payload will move to 5, but update the new sigs in control5 */
if (task.IsEmpty())
memset(toFill, 0, 8);
else
memcpy(toFill, task.toSend, 8);
/* zero first two bytes - these are reserved. */
toFill[0] = 0;
toFill[1] = 0;
}
/**
* Called in various places to double check we are using the best control frame.
* If the Talon firmware is too old, use control 1 framing, which does not allow
* setting
* control signals until robot is enabled. If Talon firmware can suport
* control5, use that
* since that frame can be transmitted during robot-disable. If calling
* application
* uses setParam to set the signal eLegacyControlMode, caller can force using
* control1
* if needed for some reason.
*/
void CanTalonSRX::UpdateControlId() {
uint8_t work[8];
uint32_t frameToUse;
/* deduce if we should change IDs. If firm supports the new frame, and
* calling app isn't forcing legacy mode
* use control5.*/
if (_useControl5ifSupported && IsControl5Supported()) {
frameToUse = CONTROL_5;
} else {
frameToUse = CONTROL_1;
}
/* is there anything to do */
if (frameToUse == _controlFrameArbId) {
/* nothing to do, we are using the best frame. */
} else if (frameToUse == CONTROL_5) {
/* get a copy of the control frame */
GetControlFrameCopy(work);
/* Change control1's DLC to 2. Passing nullptr means all payload bytes are
* zero. */
RegisterTx(CONTROL_1 | GetDeviceNumber(), _enablePeriodMs, 2, nullptr);
/* reregister the control frame using the new ID */
RegisterTx(frameToUse | GetDeviceNumber(), _controlPeriodMs, 8, work);
/* save the correct frame ArbID */
_controlFrameArbId = frameToUse;
} else if (frameToUse == CONTROL_1) {
GetControlFrameCopy(work);
/* stop sending control 5 */
UnregisterTx(CONTROL_5 | GetDeviceNumber());
/* reregister the control frame using the new ID */
RegisterTx(frameToUse | GetDeviceNumber(), _controlPeriodMs, 8, work);
/* save the correct frame ArbID */
_controlFrameArbId = frameToUse;
}
}
void CanTalonSRX::OpenSessionIfNeedBe() {
_can_stat = 0;
if (_can_h == 0) {
/* bit30 - bit8 must match $000002XX. Top bit is not masked to get remote
* frames */
FRC_NetworkCommunication_CANSessionMux_openStreamSession(
&_can_h, kParamArbIdValue | GetDeviceNumber(), kParamArbIdMask,
kMsgCapacity, &_can_stat);
if (_can_stat == 0) {
/* success */
} else {
/* something went wrong, try again later */
_can_h = 0;
}
}
}
void CanTalonSRX::ProcessStreamMessages() {
if (0 == _can_h) OpenSessionIfNeedBe();
/* process receive messages */
uint32_t i;
uint32_t messagesToRead = sizeof(_msgBuff) / sizeof(_msgBuff[0]);
uint32_t messagesRead = 0;
/* read out latest bunch of messages */
_can_stat = 0;
if (_can_h) {
FRC_NetworkCommunication_CANSessionMux_readStreamSession(
_can_h, _msgBuff, messagesToRead, &messagesRead, &_can_stat);
}
/* loop thru each message of interest */
for (i = 0; i < messagesRead; ++i) {
tCANStreamMessage *msg = _msgBuff + i;
if (msg->messageID == (PARAM_RESPONSE | GetDeviceNumber())) {
TALON_Param_Response_t *paramResp = (TALON_Param_Response_t *)msg->data;
/* decode value */
int32_t val = paramResp->ParamValueH;
val <<= 8;
val |= paramResp->ParamValueMH;
val <<= 8;
val |= paramResp->ParamValueML;
val <<= 8;
val |= paramResp->ParamValueL;
/* save latest signal */
_sigs[paramResp->ParamEnum] = val;
} else {
int brkpthere = 42;
++brkpthere;
}
}
}
void CanTalonSRX::Set(double value) {
if (value > 1)
value = 1;
else if (value < -1)
value = -1;
SetDemand(1023 * value); /* must be within [-1023,1023] */
}
/*---------------------setters and getters that use the param
* request/response-------------*/
/**
* Send a one shot frame to set an arbitrary signal.
* Most signals are in the control frame so avoid using this API unless you have
* to.
* Use this api for...
* -A motor controller profile signal eProfileParam_XXXs. These are backed up
* in flash. If you are gain-scheduling then call this periodically.
* -Default brake and limit switch signals... eOnBoot_XXXs. Avoid doing this,
* use the override signals in the control frame.
* Talon will automatically send a PARAM_RESPONSE after the set, so
* GetParamResponse will catch the latest value after a couple ms.
*/
CTR_Code CanTalonSRX::SetParamRaw(unsigned paramEnum, int rawBits) {
/* caller is using param API. Open session if it hasn'T been done. */
if (0 == _can_h) OpenSessionIfNeedBe();
TALON_Param_Response_t frame;
memset(&frame, 0, sizeof(frame));
frame.ParamEnum = paramEnum;
frame.ParamValueH = rawBits >> 0x18;
frame.ParamValueMH = rawBits >> 0x10;
frame.ParamValueML = rawBits >> 0x08;
frame.ParamValueL = rawBits;
int32_t status = 0;
FRC_NetworkCommunication_CANSessionMux_sendMessage(
PARAM_SET | GetDeviceNumber(), (const uint8_t *)&frame, 5, 0, &status);
/* small hook here if we want the API itself to react to set commands */
switch (paramEnum) {
case eLegacyControlMode:
if (rawBits != 0) {
/* caller wants to force legacy framing */
_useControl5ifSupported = false;
} else {
/* caller wants to let the API decide */
_useControl5ifSupported = true;
}
/* recheck IDs now that flag has changed */
UpdateControlId();
break;
}
/* for now have a general failure if we can't transmit */
if (status) return CTR_TxFailed;
return CTR_OKAY;
}
/**
* Checks cached CAN frames and updating solicited signals.
*/
CTR_Code CanTalonSRX::GetParamResponseRaw(unsigned paramEnum, int &rawBits) {
CTR_Code retval = CTR_OKAY;
/* process received param events. We don't expect many since this API is not
* used often. */
ProcessStreamMessages();
/* grab the solicited signal value */
sigs_t::iterator i = _sigs.find(paramEnum);
if (i == _sigs.end()) {
retval = CTR_SigNotUpdated;
} else {
rawBits = i->second;
}
return retval;
}
/**
* Asks TALON to immedietely respond with signal value. This API is only used
* for signals that are not sent periodically.
* This can be useful for reading params that rarely change like Limit Switch
* settings and PIDF values.
* @param param to request.
*/
CTR_Code CanTalonSRX::RequestParam(param_t paramEnum) {
/* process received param events. We don't expect many since this API is not
* used often. */
ProcessStreamMessages();
TALON_Param_Request_t frame;
memset(&frame, 0, sizeof(frame));
frame.ParamEnum = paramEnum;
int32_t status = 0;
FRC_NetworkCommunication_CANSessionMux_sendMessage(
PARAM_REQUEST | GetDeviceNumber(), (const uint8_t *)&frame, 1, 0,
&status);
if (status) return CTR_TxFailed;
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetParam(param_t paramEnum, double value) {
int32_t rawbits = 0;
switch (paramEnum) {
case eProfileParamSlot0_P: /* unsigned 10.22 fixed pt value */
case eProfileParamSlot0_I:
case eProfileParamSlot0_D:
case eProfileParamSlot1_P:
case eProfileParamSlot1_I:
case eProfileParamSlot1_D: {
uint32_t urawbits;
value = std::min(
value, 1023.0); /* bounds check doubles that are outside u10.22 */
value = std::max(value, 0.0);
urawbits = value * FLOAT_TO_FXP_10_22; /* perform unsign arithmetic */
rawbits = urawbits; /* copy bits over. SetParamRaw just stuffs into CAN
frame with no sense of signedness */
} break;
case eProfileParamSlot1_F: /* signed 10.22 fixed pt value */
case eProfileParamSlot0_F:
value = std::min(
value, 512.0); /* bounds check doubles that are outside s10.22 */
value = std::max(value, -512.0);
rawbits = value * FLOAT_TO_FXP_10_22;
break;
case eProfileParamVcompRate: /* unsigned 0.8 fixed pt value volts per ms */
/* within [0,1) volts per ms.
Slowest ramp is 1/256 VperMilliSec or 3.072 seconds from 0-to-12V.
Fastest ramp is 255/256 VperMilliSec or 12.1ms from 0-to-12V.
*/
if (value <= 0) {
/* negative or zero (disable), send raw value of zero */
rawbits = 0;
} else {
/* nonzero ramping */
rawbits = value * FLOAT_TO_FXP_0_8;
/* since whole part is cleared, cap to just under whole unit */
if (rawbits > (FLOAT_TO_FXP_0_8 - 1)) rawbits = (FLOAT_TO_FXP_0_8 - 1);
/* since ramping is nonzero, cap to smallest ramp rate possible */
if (rawbits == 0) {
/* caller is providing a nonzero ramp rate that's too small
to serialize, so cap to smallest possible */
rawbits = 1;
}
}
break;
default: /* everything else is integral */
rawbits = (int32_t)value;
break;
}
return SetParamRaw(paramEnum, rawbits);
}
CTR_Code CanTalonSRX::GetParamResponse(param_t paramEnum, double &value) {
int32_t rawbits = 0;
CTR_Code retval = GetParamResponseRaw(paramEnum, rawbits);
switch (paramEnum) {
case eProfileParamSlot0_P: /* 10.22 fixed pt value */
case eProfileParamSlot0_I:
case eProfileParamSlot0_D:
case eProfileParamSlot0_F:
case eProfileParamSlot1_P:
case eProfileParamSlot1_I:
case eProfileParamSlot1_D:
case eProfileParamSlot1_F:
case eCurrent:
case eTemp:
case eBatteryV:
value = ((double)rawbits) * FXP_TO_FLOAT_10_22;
break;
case eProfileParamVcompRate:
value = ((double)rawbits) * FXP_TO_FLOAT_0_8;
break;
default: /* everything else is integral */
value = (double)rawbits;
break;
}
return retval;
}
CTR_Code CanTalonSRX::GetParamResponseInt32(param_t paramEnum, int &value) {
double dvalue = 0;
CTR_Code retval = GetParamResponse(paramEnum, dvalue);
value = (int32_t)dvalue;
return retval;
}
/*----- getters and setters that use param request/response. These signals are
* backed up in flash and will survive a power cycle. ---------*/
/*----- If your application requires changing these values consider using both
* slots and switch between slot0 <=> slot1. ------------------*/
/*----- If your application requires changing these signals frequently then it
* makes sense to leverage this API. --------------------------*/
/*----- Getters don't block, so it may require several calls to get the latest
* value. --------------------------*/
CTR_Code CanTalonSRX::SetPgain(unsigned slotIdx, double gain) {
if (slotIdx == 0) return SetParam(eProfileParamSlot0_P, gain);
return SetParam(eProfileParamSlot1_P, gain);
}
CTR_Code CanTalonSRX::SetIgain(unsigned slotIdx, double gain) {
if (slotIdx == 0) return SetParam(eProfileParamSlot0_I, gain);
return SetParam(eProfileParamSlot1_I, gain);
}
CTR_Code CanTalonSRX::SetDgain(unsigned slotIdx, double gain) {
if (slotIdx == 0) return SetParam(eProfileParamSlot0_D, gain);
return SetParam(eProfileParamSlot1_D, gain);
}
CTR_Code CanTalonSRX::SetFgain(unsigned slotIdx, double gain) {
if (slotIdx == 0) return SetParam(eProfileParamSlot0_F, gain);
return SetParam(eProfileParamSlot1_F, gain);
}
CTR_Code CanTalonSRX::SetIzone(unsigned slotIdx, int zone) {
if (slotIdx == 0) return SetParam(eProfileParamSlot0_IZone, zone);
return SetParam(eProfileParamSlot1_IZone, zone);
}
CTR_Code CanTalonSRX::SetCloseLoopRampRate(unsigned slotIdx,
int closeLoopRampRate) {
if (slotIdx == 0)
return SetParam(eProfileParamSlot0_CloseLoopRampRate, closeLoopRampRate);
return SetParam(eProfileParamSlot1_CloseLoopRampRate, closeLoopRampRate);
}
CTR_Code CanTalonSRX::SetVoltageCompensationRate(double voltagePerMs) {
return SetParam(eProfileParamVcompRate, voltagePerMs);
}
CTR_Code CanTalonSRX::GetPgain(unsigned slotIdx, double &gain) {
if (slotIdx == 0) return GetParamResponse(eProfileParamSlot0_P, gain);
return GetParamResponse(eProfileParamSlot1_P, gain);
}
CTR_Code CanTalonSRX::GetIgain(unsigned slotIdx, double &gain) {
if (slotIdx == 0) return GetParamResponse(eProfileParamSlot0_I, gain);
return GetParamResponse(eProfileParamSlot1_I, gain);
}
CTR_Code CanTalonSRX::GetDgain(unsigned slotIdx, double &gain) {
if (slotIdx == 0) return GetParamResponse(eProfileParamSlot0_D, gain);
return GetParamResponse(eProfileParamSlot1_D, gain);
}
CTR_Code CanTalonSRX::GetFgain(unsigned slotIdx, double &gain) {
if (slotIdx == 0) return GetParamResponse(eProfileParamSlot0_F, gain);
return GetParamResponse(eProfileParamSlot1_F, gain);
}
CTR_Code CanTalonSRX::GetIzone(unsigned slotIdx, int &zone) {
if (slotIdx == 0)
return GetParamResponseInt32(eProfileParamSlot0_IZone, zone);
return GetParamResponseInt32(eProfileParamSlot1_IZone, zone);
}
CTR_Code CanTalonSRX::GetCloseLoopRampRate(unsigned slotIdx,
int &closeLoopRampRate) {
if (slotIdx == 0)
return GetParamResponseInt32(eProfileParamSlot0_CloseLoopRampRate,
closeLoopRampRate);
return GetParamResponseInt32(eProfileParamSlot1_CloseLoopRampRate,
closeLoopRampRate);
}
CTR_Code CanTalonSRX::GetVoltageCompensationRate(double &voltagePerMs) {
return GetParamResponse(eProfileParamVcompRate, voltagePerMs);
}
CTR_Code CanTalonSRX::SetSensorPosition(int pos) {
return SetParam(eSensorPosition, pos);
}
CTR_Code CanTalonSRX::SetForwardSoftLimit(int forwardLimit) {
return SetParam(eProfileParamSoftLimitForThreshold, forwardLimit);
}
CTR_Code CanTalonSRX::SetReverseSoftLimit(int reverseLimit) {
return SetParam(eProfileParamSoftLimitRevThreshold, reverseLimit);
}
CTR_Code CanTalonSRX::SetForwardSoftEnable(int enable) {
return SetParam(eProfileParamSoftLimitForEnable, enable);
}
CTR_Code CanTalonSRX::SetReverseSoftEnable(int enable) {
return SetParam(eProfileParamSoftLimitRevEnable, enable);
}
CTR_Code CanTalonSRX::GetForwardSoftLimit(int &forwardLimit) {
return GetParamResponseInt32(eProfileParamSoftLimitForThreshold,
forwardLimit);
}
CTR_Code CanTalonSRX::GetReverseSoftLimit(int &reverseLimit) {
return GetParamResponseInt32(eProfileParamSoftLimitRevThreshold,
reverseLimit);
}
CTR_Code CanTalonSRX::GetForwardSoftEnable(int &enable) {
return GetParamResponseInt32(eProfileParamSoftLimitForEnable, enable);
}
CTR_Code CanTalonSRX::GetReverseSoftEnable(int &enable) {
return GetParamResponseInt32(eProfileParamSoftLimitRevEnable, enable);
}
/**
* @param param [out] Rise to fall time period in microseconds.
*/
CTR_Code CanTalonSRX::GetPulseWidthRiseToFallUs(int &param) {
int temp = 0;
int periodUs = 0;
/* first grab our 12.12 position */
CTR_Code retval1 = GetPulseWidthPosition(temp);
/* mask off number of turns */
temp &= 0xFFF;
/* next grab the waveform period. This value
* will be zero if we stop getting pulses **/
CTR_Code retval2 = GetPulseWidthRiseToRiseUs(periodUs);
/* now we have 0.12 position that is scaled to the waveform period.
Use fixed pt multiply to scale our 0.16 period into us.*/
param = (temp * periodUs) / BIT12;
/* pass the worst error code to caller.
Assume largest value is the most pressing error code.*/
return (CTR_Code)std::max((int)retval1, (int)retval2);
}
CTR_Code CanTalonSRX::IsPulseWidthSensorPresent(int &param) {
int periodUs = 0;
CTR_Code retval = GetPulseWidthRiseToRiseUs(periodUs);
/* if a nonzero period is present, we are getting good pules.
Otherwise the sensor is not present. */
if (periodUs != 0)
param = 1;
else
param = 0;
return retval;
}
/**
* @param modeSelect selects which mode.
* @param demand setpt or throttle or masterId to follow.
* @return error code, 0 iff successful.
* This function has the advantage of atomically setting mode and demand.
*/
CTR_Code CanTalonSRX::SetModeSelect(int modeSelect, int demand) {
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill =
GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId |
GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->ModeSelect = modeSelect;
toFill->DemandH = demand >> 16;
toFill->DemandM = demand >> 8;
toFill->DemandL = demand >> 0;
FlushTx(toFill);
return CTR_OKAY;
}
/**
* Change the periodMs of a TALON's status frame. See kStatusFrame_* enums for
* what's available.
*/
CTR_Code CanTalonSRX::SetStatusFrameRate(unsigned frameEnum,
unsigned periodMs) {
CTR_Code retval = CTR_OKAY;
int32_t paramEnum = 0;
/* bounds check the period */
if (periodMs < 1)
periodMs = 1;
else if (periodMs > 255)
periodMs = 255;
uint8_t period = (uint8_t)periodMs;
/* lookup the correct param enum based on what frame to rate-change */
switch (frameEnum) {
case kStatusFrame_General:
paramEnum = eStatus1FrameRate;
break;
case kStatusFrame_Feedback:
paramEnum = eStatus2FrameRate;
break;
case kStatusFrame_Encoder:
paramEnum = eStatus3FrameRate;
break;
case kStatusFrame_AnalogTempVbat:
paramEnum = eStatus4FrameRate;
break;
case kStatusFrame_PulseWidthMeas:
paramEnum = eStatus8FrameRate;
break;
case kStatusFrame_MotionProfile:
paramEnum = eStatus9FrameRate;
break;
default:
/* caller's request is not support, return an error code */
retval = CTR_InvalidParamValue;
break;
}
/* if lookup was succesful, send set-request out */
if (retval == CTR_OKAY) {
/* paramEnum is updated, sent it out */
retval = SetParamRaw(paramEnum, period);
}
return retval;
}
/**
* Clear all sticky faults in TALON.
*/
CTR_Code CanTalonSRX::ClearStickyFaults() {
int32_t status = 0;
/* build request frame */
TALON_Control_3_ClearFlags_OneShot_t frame;
memset(&frame, 0, sizeof(frame));
frame.ClearStickyFaults = 1;
FRC_NetworkCommunication_CANSessionMux_sendMessage(
CONTROL_3 | GetDeviceNumber(), (const uint8_t *)&frame, sizeof(frame), 0,
&status);
if (status) return CTR_TxFailed;
return CTR_OKAY;
}
/**
* @return the tx task that transmits Control6 (motion profile control).
* If it's not scheduled, then schedule it. This is part of firing
* the MotionProf framing only when needed to save bandwidth.
*/
CtreCanNode::txTask<TALON_Control_6_MotProfAddTrajPoint_t>
CanTalonSRX::GetControl6() {
CtreCanNode::txTask<TALON_Control_6_MotProfAddTrajPoint_t> control6 =
GetTx<TALON_Control_6_MotProfAddTrajPoint_t>(CONTROL_6 |
GetDeviceNumber());
if (control6.IsEmpty()) {
/* control6 never started, arm it now */
RegisterTx(CONTROL_6 | GetDeviceNumber(), _control6PeriodMs);
control6 = GetTx<TALON_Control_6_MotProfAddTrajPoint_t>(CONTROL_6 |
GetDeviceNumber());
control6->Idx = 0;
_motProfFlowControl = 0;
FlushTx(control6);
}
return control6;
}
/**
* Calling application can opt to speed up the handshaking between the robot API
* and the Talon to increase the download rate of the Talon's Motion Profile.
* Ideally the period should be no more than half the period of a trajectory
* point.
*/
void CanTalonSRX::ChangeMotionControlFramePeriod(uint32_t periodMs) {
std::unique_lock<std::mutex> lock(_mutMotProf);
/* if message is already registered, it will get updated.
* Otherwise it will error if it hasn't been setup yet, but that's ok
* because the _control6PeriodMs will be used later.
* @see GetControl6
*/
_control6PeriodMs = periodMs;
ChangeTxPeriod(CONTROL_6 | GetDeviceNumber(), _control6PeriodMs);
}
/**
* Clear the buffered motion profile in both Talon RAM (bottom), and in the API
* (top).
*/
void CanTalonSRX::ClearMotionProfileTrajectories() {
std::unique_lock<std::mutex> lock(_mutMotProf);
/* clear the top buffer */
_motProfTopBuffer.Clear();
/* send signal to clear bottom buffer */
auto toFill = CanTalonSRX::GetControl6();
toFill->Idx = 0;
_motProfFlowControl = 0; /* match the transmitted flow control */
FlushTx(toFill);
}
/**
* Retrieve just the buffer count for the api-level (top) buffer.
* This routine performs no CAN or data structure lookups, so its fast and ideal
* if caller needs to quickly poll the progress of trajectory points being
* emptied into Talon's RAM. Otherwise just use GetMotionProfileStatus.
* @return number of trajectory points in the top buffer.
*/
uint32_t CanTalonSRX::GetMotionProfileTopLevelBufferCount() {
std::unique_lock<std::mutex> lock(_mutMotProf);
uint32_t retval = (uint32_t)_motProfTopBuffer.GetNumTrajectories();
return retval;
}
/**
* Retrieve just the buffer full for the api-level (top) buffer.
* This routine performs no CAN or data structure lookups, so its fast and ideal
* if caller needs to quickly poll. Otherwise just use GetMotionProfileStatus.
* @return number of trajectory points in the top buffer.
*/
bool CanTalonSRX::IsMotionProfileTopLevelBufferFull() {
std::unique_lock<std::mutex> lock(_mutMotProf);
if (_motProfTopBuffer.GetNumTrajectories() >= kMotionProfileTopBufferCapacity)
return true;
return false;
}
/**
* Push another trajectory point into the top level buffer (which is emptied
* into the Talon's bottom buffer as room allows).
* @param targPos servo position in native Talon units (sensor units).
* @param targVel velocity to feed-forward in native Talon units (sensor units
* per 100ms).
* @param profileSlotSelect which slot to pull PIDF gains from. Currently
* supports 0 or 1.
* @param timeDurMs time in milliseconds of how long to apply this point.
* @param velOnly set to nonzero to signal Talon that only the feed-foward
* velocity should be used, i.e. do not perform PID on position.
* This is equivalent to setting PID gains to zero, but much
* more efficient and synchronized to MP.
* @param isLastPoint set to nonzero to signal Talon to keep processing this
* trajectory point, instead of jumping to the next one
* when timeDurMs expires. Otherwise MP executer will
* eventually see an empty buffer after the last point
* expires, causing it to assert the IsUnderRun flag.
* However this may be desired if calling application
* never wants to terminate the MP.
* @param zeroPos set to nonzero to signal Talon to "zero" the selected
* position sensor before executing this trajectory point.
* Typically the first point should have this set only thus
* allowing the remainder of the MP positions to be relative to
* zero.
* @return CTR_OKAY if trajectory point push ok. CTR_BufferFull if buffer is
* full due to kMotionProfileTopBufferCapacity.
*/
CTR_Code CanTalonSRX::PushMotionProfileTrajectory(int targPos, int targVel,
int profileSlotSelect,
int timeDurMs, int velOnly,
int isLastPoint,
int zeroPos) {
ReactToMotionProfileCall();
/* create our trajectory point */
TALON_Control_6_MotProfAddTrajPoint_huff0_t traj;
memset((void *)&traj, 0, sizeof(traj));
traj.NextPt_ZeroPosition = zeroPos ? 1 : 0;
traj.NextPt_VelOnly = velOnly ? 1 : 0;
traj.NextPt_IsLast = isLastPoint ? 1 : 0;
traj.NextPt_ProfileSlotSelect = (profileSlotSelect > 0) ? 1 : 0;
if (timeDurMs < 0)
timeDurMs = 0;
else if (timeDurMs > 255)
timeDurMs = 255;
traj.NextPt_DurationMs = timeDurMs;
traj.NextPt_VelocityH = targVel >> 0x08;
traj.NextPt_VelocityL = targVel & 0xFF;
traj.NextPt_PositionH = targPos >> 0x10;
traj.NextPt_PositionM = targPos >> 0x08;
traj.NextPt_PositionL = targPos & 0xFF;
std::unique_lock<std::mutex> lock(_mutMotProf);
if (_motProfTopBuffer.GetNumTrajectories() >= kMotionProfileTopBufferCapacity)
return CTR_BufferFull;
_motProfTopBuffer.Push(traj);
return CTR_OKAY;
}
/**
* Increment our flow control to manage streaming to the Talon.
* f(x) = { 1, x = 15,
* x+1, x < 15
* }
*/
#define MotionProf_IncrementSync(idx) ((idx >= 15) ? 1 : 0) + ((idx + 1) & 0xF)
/**
* Update the NextPt signals inside the control frame given the next pt to send.
* @param control pointer to the CAN frame payload containing control6. Only
* the signals that serialize the next trajectory point are updated from the
* contents of newPt.
* @param newPt point to the next trajectory that needs to be inserted into
* Talon RAM.
*/
void CanTalonSRX::CopyTrajPtIntoControl(
TALON_Control_6_MotProfAddTrajPoint_t *control,
const TALON_Control_6_MotProfAddTrajPoint_t *newPt) {
/* Bring over the common signals in the first two bytes */
control->NextPt_ProfileSlotSelect = newPt->NextPt_ProfileSlotSelect;
control->NextPt_ZeroPosition = newPt->NextPt_ZeroPosition;
control->NextPt_VelOnly = newPt->NextPt_VelOnly;
control->NextPt_IsLast = newPt->NextPt_IsLast;
control->huffCode = newPt->huffCode;
/* the last six bytes are entirely for hold NextPt's values. */
uint8_t *dest = (uint8_t *)control;
const uint8_t *src = (const uint8_t *)newPt;
dest[2] = src[2];
dest[3] = src[3];
dest[4] = src[4];
dest[5] = src[5];
dest[6] = src[6];
dest[7] = src[7];
}
/**
* Caller is either pushing a new motion profile point, or is
* calling the Process buffer routine. In either case check our
* flow control to see if we need to start sending control6.
*/
void CanTalonSRX::ReactToMotionProfileCall() {
if (_motProfFlowControl < 0) {
/* we have not yet armed the periodic frame. We do this lazilly to
* save bus utilization since most Talons on the bus probably are not
* MP'ing.
*/
ClearMotionProfileTrajectories(); /* this moves flow control so only fires
once if ever */
}
}
/**
* This must be called periodically to funnel the trajectory points from the
* API's top level buffer to the Talon's bottom level buffer. Recommendation
* is to call this twice as fast as the executation rate of the motion profile.
* So if MP is running with 20ms trajectory points, try calling this routine
* every 10ms. All motion profile functions are thread-safe through the use of
* a mutex, so there is no harm in having the caller utilize threading.
*/
void CanTalonSRX::ProcessMotionProfileBuffer() {
ReactToMotionProfileCall();
/* get the latest status frame */
GET_STATUS9();
/* lock */
std::unique_lock<std::mutex> lock(_mutMotProf);
/* calc what we expect to receive */
if (_motProfFlowControl == rx->NextID) {
/* Talon has completed the last req */
if (_motProfTopBuffer.IsEmpty()) {
/* nothing to do */
} else {
/* get the latest control frame */
auto toFill = GetControl6();
TALON_Control_6_MotProfAddTrajPoint_t *front = _motProfTopBuffer.Front();
CopyTrajPtIntoControl(toFill.toSend, front);
_motProfTopBuffer.Pop();
_motProfFlowControl = MotionProf_IncrementSync(_motProfFlowControl);
toFill->Idx = _motProfFlowControl;
FlushTx(toFill);
}
} else {
/* still waiting on Talon */
}
}
/**
* Retrieve all status information.
* Since this all comes from one CAN frame, its ideal to have one routine to
* retrieve the frame once and decode everything.
* @param [out] flags bitfield for status bools. Starting with least
* significant bit: IsValid, HasUnderrun, IsUnderrun, IsLast, VelOnly.
*
* IsValid set when MP executer is processing a trajectory point,
* and that point's status is instrumented with IsLast,
* VelOnly, targPos, targVel. However if MP executor is
* not processing a trajectory point, then this flag is
* false, and the instrumented signals will be zero.
* HasUnderrun is set anytime the MP executer is ready to pop
* another trajectory point from the Talon's RAM,
* but the buffer is empty. It can only be cleared
* by using SetParam(eMotionProfileHasUnderrunErr,0);
* IsUnderrun is set when the MP executer is ready for another
* point, but the buffer is empty, and cleared when
* the MP executer does not need another point.
* HasUnderrun shadows this registor when this
* register gets set, however HasUnderrun stays
* asserted until application has process it, and
* IsUnderrun auto-clears when the condition is
* resolved.
* IsLast is set/cleared based on the MP executer's current
* trajectory point's IsLast value. This assumes
* IsLast was set when PushMotionProfileTrajectory
* was used to insert the currently processed trajectory
* point.
* VelOnly is set/cleared based on the MP executer's current
* trajectory point's VelOnly value.
*
* @param [out] profileSlotSelect The currently processed trajectory point's
* selected slot. This can differ in the currently selected slot used
* for Position and Velocity servo modes.
* @param [out] targPos The currently processed trajectory point's position
* in native units. This param is zero if IsValid is zero.
* @param [out] targVel The currently processed trajectory point's velocity
* in native units. This param is zero if IsValid is zero.
* @param [out] topBufferRem The remaining number of points in the top level
* buffer.
* @param [out] topBufferCnt The number of points in the top level buffer to
* be sent to Talon.
* @param [out] btmBufferCnt The number of points in the bottom level buffer
* inside Talon.
* @return CTR error code
*/
CTR_Code CanTalonSRX::GetMotionProfileStatus(
uint32_t &flags, uint32_t &profileSlotSelect, int32_t &targPos,
int32_t &targVel, uint32_t &topBufferRem, uint32_t &topBufferCnt,
uint32_t &btmBufferCnt, uint32_t &outputEnable) {
/* get the latest status frame */
GET_STATUS9();
/* clear signals in case we never received an update, caller should check
* return
*/
flags = 0;
profileSlotSelect = 0;
targPos = 0;
targVel = 0;
btmBufferCnt = 0;
/* these signals are always available */
topBufferCnt = _motProfTopBuffer.GetNumTrajectories();
topBufferRem =
kMotionProfileTopBufferCapacity - _motProfTopBuffer.GetNumTrajectories();
/* TODO: make enums or make a better method prototype */
if (rx->ActTraj_IsValid) flags |= kMotionProfileFlag_ActTraj_IsValid;
if (rx->HasUnderrun) flags |= kMotionProfileFlag_HasUnderrun;
if (rx->IsUnderrun) flags |= kMotionProfileFlag_IsUnderrun;
if (rx->ActTraj_IsLast) flags |= kMotionProfileFlag_ActTraj_IsLast;
if (rx->ActTraj_VelOnly) flags |= kMotionProfileFlag_ActTraj_VelOnly;
btmBufferCnt = rx->Count;
targPos = rx->ActTraj_PositionH;
targPos <<= 8;
targPos |= rx->ActTraj_PositionM;
targPos <<= 8;
targPos |= rx->ActTraj_PositionL;
targVel = rx->ActTraj_VelocityH;
targVel <<= 8;
targVel |= rx->ActTraj_VelocityL;
profileSlotSelect = rx->ActTraj_ProfileSlotSelect;
switch (rx->OutputType) {
case kMotionProf_Disabled:
case kMotionProf_Enable:
case kMotionProf_Hold:
outputEnable = rx->OutputType;
break;
default:
/* do now allow invalid values for sake of user-facing enum types */
outputEnable = kMotionProf_Disabled;
break;
}
return rx.err;
}
//------------------------ auto generated ------------------------------------//
/* This API is optimal since it uses the fire-and-forget CAN interface.
* These signals should cover the majority of all use cases.
*/
CTR_Code CanTalonSRX::GetFault_OverTemp(int &param)
{
GET_STATUS1();
param = rx->Fault_OverTemp;
return rx.err;
}
CTR_Code CanTalonSRX::GetFault_UnderVoltage(int &param)
{
GET_STATUS1();
param = rx->Fault_UnderVoltage;
return rx.err;
}
CTR_Code CanTalonSRX::GetFault_ForLim(int &param)
{
GET_STATUS1();
param = rx->Fault_ForLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetFault_RevLim(int &param)
{
GET_STATUS1();
param = rx->Fault_RevLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetFault_HardwareFailure(int &param)
{
GET_STATUS1();
param = rx->Fault_HardwareFailure;
return rx.err;
}
CTR_Code CanTalonSRX::GetFault_ForSoftLim(int &param)
{
GET_STATUS1();
param = rx->Fault_ForSoftLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetFault_RevSoftLim(int &param)
{
GET_STATUS1();
param = rx->Fault_RevSoftLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetStckyFault_OverTemp(int &param)
{
GET_STATUS2();
param = rx->StckyFault_OverTemp;
return rx.err;
}
CTR_Code CanTalonSRX::GetStckyFault_UnderVoltage(int &param)
{
GET_STATUS2();
param = rx->StckyFault_UnderVoltage;
return rx.err;
}
CTR_Code CanTalonSRX::GetStckyFault_ForLim(int &param)
{
GET_STATUS2();
param = rx->StckyFault_ForLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetStckyFault_RevLim(int &param)
{
GET_STATUS2();
param = rx->StckyFault_RevLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetStckyFault_ForSoftLim(int &param)
{
GET_STATUS2();
param = rx->StckyFault_ForSoftLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetStckyFault_RevSoftLim(int &param)
{
GET_STATUS2();
param = rx->StckyFault_RevSoftLim;
return rx.err;
}
CTR_Code CanTalonSRX::GetAppliedThrottle(int &param)
{
GET_STATUS1();
int32_t raw = 0;
raw |= rx->AppliedThrottle_h3;
raw <<= 8;
raw |= rx->AppliedThrottle_l8;
raw <<= (32-11); /* sign extend */
raw >>= (32-11); /* sign extend */
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetCloseLoopErr(int &param)
{
GET_STATUS1();
int32_t raw = 0;
raw |= rx->CloseLoopErrH;
raw <<= 16 - 8;
raw |= rx->CloseLoopErrM;
raw <<= 8;
raw |= rx->CloseLoopErrL;
raw <<= (32-24); /* sign extend */
raw >>= (32-24); /* sign extend */
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetFeedbackDeviceSelect(int &param)
{
GET_STATUS1();
param = rx->FeedbackDeviceSelect;
return rx.err;
}
CTR_Code CanTalonSRX::GetModeSelect(int &param)
{
GET_STATUS1();
uint32_t raw = 0;
raw |= rx->ModeSelect_h1;
raw <<= 3;
raw |= rx->ModeSelect_b3;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetLimitSwitchEn(int &param)
{
GET_STATUS1();
param = rx->LimitSwitchEn;
return rx.err;
}
CTR_Code CanTalonSRX::GetLimitSwitchClosedFor(int &param)
{
GET_STATUS1();
param = rx->LimitSwitchClosedFor;
return rx.err;
}
CTR_Code CanTalonSRX::GetLimitSwitchClosedRev(int &param)
{
GET_STATUS1();
param = rx->LimitSwitchClosedRev;
return rx.err;
}
CTR_Code CanTalonSRX::GetSensorPosition(int &param)
{
GET_STATUS2();
int32_t raw = 0;
raw |= rx->SensorPositionH;
raw <<= 16 - 8;
raw |= rx->SensorPositionM;
raw <<= 8;
raw |= rx->SensorPositionL;
raw <<= (32-24); /* sign extend */
raw >>= (32-24); /* sign extend */
if(rx->PosDiv8)
raw *= 8;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetSensorVelocity(int &param)
{
GET_STATUS2();
int32_t raw = 0;
raw |= rx->SensorVelocityH;
raw <<= 8;
raw |= rx->SensorVelocityL;
raw <<= (32-16); /* sign extend */
raw >>= (32-16); /* sign extend */
if(rx->VelDiv4)
raw *= 4;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetCurrent(double &param)
{
GET_STATUS2();
uint32_t raw = 0;
raw |= rx->Current_h8;
raw <<= 2;
raw |= rx->Current_l2;
param = (double)raw * 0.125 + 0;
return rx.err;
}
CTR_Code CanTalonSRX::GetBrakeIsEnabled(int &param)
{
GET_STATUS2();
param = rx->BrakeIsEnabled;
return rx.err;
}
CTR_Code CanTalonSRX::GetEncPosition(int &param)
{
GET_STATUS3();
int32_t raw = 0;
raw |= rx->EncPositionH;
raw <<= 16 - 8;
raw |= rx->EncPositionM;
raw <<= 8;
raw |= rx->EncPositionL;
raw <<= (32-24); /* sign extend */
raw >>= (32-24); /* sign extend */
if(rx->PosDiv8)
raw *= 8;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetEncVel(int &param)
{
GET_STATUS3();
int32_t raw = 0;
raw |= rx->EncVelH;
raw <<= 8;
raw |= rx->EncVelL;
raw <<= (32-16); /* sign extend */
raw >>= (32-16); /* sign extend */
if(rx->VelDiv4)
raw *= 4;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetEncIndexRiseEvents(int &param)
{
GET_STATUS3();
uint32_t raw = 0;
raw |= rx->EncIndexRiseEventsH;
raw <<= 8;
raw |= rx->EncIndexRiseEventsL;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetQuadApin(int &param)
{
GET_STATUS3();
param = rx->QuadApin;
return rx.err;
}
CTR_Code CanTalonSRX::GetQuadBpin(int &param)
{
GET_STATUS3();
param = rx->QuadBpin;
return rx.err;
}
CTR_Code CanTalonSRX::GetQuadIdxpin(int &param)
{
GET_STATUS3();
param = rx->QuadIdxpin;
return rx.err;
}
CTR_Code CanTalonSRX::GetAnalogInWithOv(int &param)
{
GET_STATUS4();
int32_t raw = 0;
raw |= rx->AnalogInWithOvH;
raw <<= 16 - 8;
raw |= rx->AnalogInWithOvM;
raw <<= 8;
raw |= rx->AnalogInWithOvL;
raw <<= (32-24); /* sign extend */
raw >>= (32-24); /* sign extend */
if(rx->PosDiv8)
raw *= 8;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetAnalogInVel(int &param)
{
GET_STATUS4();
int32_t raw = 0;
raw |= rx->AnalogInVelH;
raw <<= 8;
raw |= rx->AnalogInVelL;
raw <<= (32-16); /* sign extend */
raw >>= (32-16); /* sign extend */
if(rx->VelDiv4)
raw *= 4;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetTemp(double &param)
{
GET_STATUS4();
uint32_t raw = rx->Temp;
param = (double)raw * 0.6451612903 + -50;
return rx.err;
}
CTR_Code CanTalonSRX::GetBatteryV(double &param)
{
GET_STATUS4();
uint32_t raw = rx->BatteryV;
param = (double)raw * 0.05 + 4;
return rx.err;
}
CTR_Code CanTalonSRX::GetResetCount(int &param)
{
GET_STATUS5();
uint32_t raw = 0;
raw |= rx->ResetCountH;
raw <<= 8;
raw |= rx->ResetCountL;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetResetFlags(int &param)
{
GET_STATUS5();
uint32_t raw = 0;
raw |= rx->ResetFlagsH;
raw <<= 8;
raw |= rx->ResetFlagsL;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetFirmVers(int &param)
{
GET_STATUS5();
uint32_t raw = 0;
raw |= rx->FirmVersH;
raw <<= 8;
raw |= rx->FirmVersL;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetPulseWidthPosition(int &param)
{
GET_STATUS8();
int32_t raw = 0;
raw |= rx->PulseWidPositionH;
raw <<= 16 - 8;
raw |= rx->PulseWidPositionM;
raw <<= 8;
raw |= rx->PulseWidPositionL;
raw <<= (32-24); /* sign extend */
raw >>= (32-24); /* sign extend */
if(rx->PosDiv8)
raw *= 8;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetPulseWidthVelocity(int &param)
{
GET_STATUS8();
int32_t raw = 0;
raw |= rx->PulseWidVelH;
raw <<= 8;
raw |= rx->PulseWidVelL;
raw <<= (32-16); /* sign extend */
raw >>= (32-16); /* sign extend */
if(rx->VelDiv4)
raw *= 4;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetPulseWidthRiseToRiseUs(int &param)
{
GET_STATUS8();
uint32_t raw = 0;
raw |= rx->PeriodUsM8;
raw <<= 8;
raw |= rx->PeriodUsL8;
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetActTraj_IsValid(int &param)
{
GET_STATUS9();
param = rx->ActTraj_IsValid;
return rx.err;
}
CTR_Code CanTalonSRX::GetActTraj_ProfileSlotSelect(int &param)
{
GET_STATUS9();
param = rx->ActTraj_ProfileSlotSelect;
return rx.err;
}
CTR_Code CanTalonSRX::GetActTraj_VelOnly(int &param)
{
GET_STATUS9();
param = rx->ActTraj_VelOnly;
return rx.err;
}
CTR_Code CanTalonSRX::GetActTraj_IsLast(int &param)
{
GET_STATUS9();
param = rx->ActTraj_IsLast;
return rx.err;
}
CTR_Code CanTalonSRX::GetOutputType(int &param)
{
GET_STATUS9();
param = rx->OutputType;
return rx.err;
}
CTR_Code CanTalonSRX::GetHasUnderrun(int &param)
{
GET_STATUS9();
param = rx->HasUnderrun;
return rx.err;
}
CTR_Code CanTalonSRX::GetIsUnderrun(int &param)
{
GET_STATUS9();
param = rx->IsUnderrun;
return rx.err;
}
CTR_Code CanTalonSRX::GetNextID(int &param)
{
GET_STATUS9();
param = rx->NextID;
return rx.err;
}
CTR_Code CanTalonSRX::GetBufferIsFull(int &param)
{
GET_STATUS9();
param = rx->BufferIsFull;
return rx.err;
}
CTR_Code CanTalonSRX::GetCount(int &param)
{
GET_STATUS9();
param = rx->Count;
return rx.err;
}
CTR_Code CanTalonSRX::GetActTraj_Velocity(int &param)
{
GET_STATUS9();
int32_t raw = 0;
raw |= rx->ActTraj_VelocityH;
raw <<= 8;
raw |= rx->ActTraj_VelocityL;
raw <<= (32-16); /* sign extend */
raw >>= (32-16); /* sign extend */
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::GetActTraj_Position(int &param)
{
GET_STATUS9();
int32_t raw = 0;
raw |= rx->ActTraj_PositionH;
raw <<= 16 - 8;
raw |= rx->ActTraj_PositionM;
raw <<= 8;
raw |= rx->ActTraj_PositionL;
raw <<= (32-24); /* sign extend */
raw >>= (32-24); /* sign extend */
param = (int)raw;
return rx.err;
}
CTR_Code CanTalonSRX::SetDemand(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->DemandH = param>>16;
toFill->DemandM = param>>8;
toFill->DemandL = param>>0;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetOverrideLimitSwitchEn(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->OverrideLimitSwitchEn = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetFeedbackDeviceSelect(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->FeedbackDeviceSelect = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetRevMotDuringCloseLoopEn(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->RevMotDuringCloseLoopEn = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetOverrideBrakeType(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->OverrideBrakeType = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetModeSelect(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->ModeSelect = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetProfileSlotSelect(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->ProfileSlotSelect = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetRampThrottle(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->RampThrottle = param;
FlushTx(toFill);
return CTR_OKAY;
}
CTR_Code CanTalonSRX::SetRevFeedbackSensor(int param)
{
CtreCanNode::txTask<TALON_Control_1_General_10ms_t> toFill = GetTx<TALON_Control_1_General_10ms_t>(_controlFrameArbId | GetDeviceNumber());
if (toFill.IsEmpty()) return CTR_UnexpectedArbId;
toFill->RevFeedbackSensor = param ? 1 : 0;
FlushTx(toFill);
return CTR_OKAY;
}
//------------------ C interface --------------------------------------------//
extern "C" {
void *c_TalonSRX_Create3(int deviceNumber, int controlPeriodMs, int enablePeriodMs)
{
return new CanTalonSRX(deviceNumber, controlPeriodMs, enablePeriodMs);
}
void *c_TalonSRX_Create2(int deviceNumber, int controlPeriodMs)
{
return new CanTalonSRX(deviceNumber, controlPeriodMs);
}
void *c_TalonSRX_Create1(int deviceNumber)
{
return new CanTalonSRX(deviceNumber);
}
void c_TalonSRX_Destroy(void *handle)
{
delete (CanTalonSRX*)handle;
}
void c_TalonSRX_Set(void *handle, double value)
{
return ((CanTalonSRX*)handle)->Set(value);
}
CTR_Code c_TalonSRX_SetParam(void *handle, int paramEnum, double value)
{
return ((CanTalonSRX*)handle)->SetParam((CanTalonSRX::param_t)paramEnum, value);
}
CTR_Code c_TalonSRX_RequestParam(void *handle, int paramEnum)
{
return ((CanTalonSRX*)handle)->RequestParam((CanTalonSRX::param_t)paramEnum);
}
CTR_Code c_TalonSRX_GetParamResponse(void *handle, int paramEnum, double *value)
{
return ((CanTalonSRX*)handle)->GetParamResponse((CanTalonSRX::param_t)paramEnum, *value);
}
CTR_Code c_TalonSRX_GetParamResponseInt32(void *handle, int paramEnum, int *value)
{
return ((CanTalonSRX*)handle)->GetParamResponseInt32((CanTalonSRX::param_t)paramEnum, *value);
}
CTR_Code c_TalonSRX_SetPgain(void *handle, int slotIdx, double gain)
{
return ((CanTalonSRX*)handle)->SetPgain((unsigned)slotIdx, gain);
}
CTR_Code c_TalonSRX_SetIgain(void *handle, int slotIdx, double gain)
{
return ((CanTalonSRX*)handle)->SetIgain((unsigned)slotIdx, gain);
}
CTR_Code c_TalonSRX_SetDgain(void *handle, int slotIdx, double gain)
{
return ((CanTalonSRX*)handle)->SetDgain((unsigned)slotIdx, gain);
}
CTR_Code c_TalonSRX_SetFgain(void *handle, int slotIdx, double gain)
{
return ((CanTalonSRX*)handle)->SetFgain((unsigned)slotIdx, gain);
}
CTR_Code c_TalonSRX_SetIzone(void *handle, int slotIdx, int zone)
{
return ((CanTalonSRX*)handle)->SetIzone((unsigned)slotIdx, zone);
}
CTR_Code c_TalonSRX_SetCloseLoopRampRate(void *handle, int slotIdx, int closeLoopRampRate)
{
return ((CanTalonSRX*)handle)->SetCloseLoopRampRate((unsigned)slotIdx, closeLoopRampRate);
}
CTR_Code c_TalonSRX_SetVoltageCompensationRate(void *handle, double voltagePerMs)
{
return ((CanTalonSRX*)handle)->SetVoltageCompensationRate(voltagePerMs);
}
CTR_Code c_TalonSRX_SetSensorPosition(void *handle, int pos)
{
return ((CanTalonSRX*)handle)->SetSensorPosition(pos);
}
CTR_Code c_TalonSRX_SetForwardSoftLimit(void *handle, int forwardLimit)
{
return ((CanTalonSRX*)handle)->SetForwardSoftLimit(forwardLimit);
}
CTR_Code c_TalonSRX_SetReverseSoftLimit(void *handle, int reverseLimit)
{
return ((CanTalonSRX*)handle)->SetReverseSoftLimit(reverseLimit);
}
CTR_Code c_TalonSRX_SetForwardSoftEnable(void *handle, int enable)
{
return ((CanTalonSRX*)handle)->SetForwardSoftEnable(enable);
}
CTR_Code c_TalonSRX_SetReverseSoftEnable(void *handle, int enable)
{
return ((CanTalonSRX*)handle)->SetReverseSoftEnable(enable);
}
CTR_Code c_TalonSRX_GetPgain(void *handle, int slotIdx, double *gain)
{
return ((CanTalonSRX*)handle)->GetPgain((unsigned)slotIdx, *gain);
}
CTR_Code c_TalonSRX_GetIgain(void *handle, int slotIdx, double *gain)
{
return ((CanTalonSRX*)handle)->GetIgain((unsigned)slotIdx, *gain);
}
CTR_Code c_TalonSRX_GetDgain(void *handle, int slotIdx, double *gain)
{
return ((CanTalonSRX*)handle)->GetDgain((unsigned)slotIdx, *gain);
}
CTR_Code c_TalonSRX_GetFgain(void *handle, int slotIdx, double *gain)
{
return ((CanTalonSRX*)handle)->GetFgain((unsigned)slotIdx, *gain);
}
CTR_Code c_TalonSRX_GetIzone(void *handle, int slotIdx, int *zone)
{
return ((CanTalonSRX*)handle)->GetIzone((unsigned)slotIdx, *zone);
}
CTR_Code c_TalonSRX_GetCloseLoopRampRate(void *handle, int slotIdx, int *closeLoopRampRate)
{
return ((CanTalonSRX*)handle)->GetCloseLoopRampRate((unsigned)slotIdx, *closeLoopRampRate);
}
CTR_Code c_TalonSRX_GetVoltageCompensationRate(void *handle, double *voltagePerMs)
{
return ((CanTalonSRX*)handle)->GetVoltageCompensationRate(*voltagePerMs);
}
CTR_Code c_TalonSRX_GetForwardSoftLimit(void *handle, int *forwardLimit)
{
return ((CanTalonSRX*)handle)->GetForwardSoftLimit(*forwardLimit);
}
CTR_Code c_TalonSRX_GetReverseSoftLimit(void *handle, int *reverseLimit)
{
return ((CanTalonSRX*)handle)->GetReverseSoftLimit(*reverseLimit);
}
CTR_Code c_TalonSRX_GetForwardSoftEnable(void *handle, int *enable)
{
return ((CanTalonSRX*)handle)->GetForwardSoftEnable(*enable);
}
CTR_Code c_TalonSRX_GetReverseSoftEnable(void *handle, int *enable)
{
return ((CanTalonSRX*)handle)->GetReverseSoftEnable(*enable);
}
CTR_Code c_TalonSRX_GetPulseWidthRiseToFallUs(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetPulseWidthRiseToFallUs(*param);
}
CTR_Code c_TalonSRX_IsPulseWidthSensorPresent(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->IsPulseWidthSensorPresent(*param);
}
CTR_Code c_TalonSRX_SetModeSelect2(void *handle, int modeSelect, int demand)
{
return ((CanTalonSRX*)handle)->SetModeSelect(modeSelect, demand);
}
CTR_Code c_TalonSRX_SetStatusFrameRate(void *handle, int frameEnum, int periodMs)
{
return ((CanTalonSRX*)handle)->SetStatusFrameRate((unsigned)frameEnum, (unsigned)periodMs);
}
CTR_Code c_TalonSRX_ClearStickyFaults(void *handle)
{
return ((CanTalonSRX*)handle)->ClearStickyFaults();
}
void c_TalonSRX_ChangeMotionControlFramePeriod(void *handle, int periodMs)
{
return ((CanTalonSRX*)handle)->ChangeMotionControlFramePeriod((uint32_t)periodMs);
}
void c_TalonSRX_ClearMotionProfileTrajectories(void *handle)
{
return ((CanTalonSRX*)handle)->ClearMotionProfileTrajectories();
}
int c_TalonSRX_GetMotionProfileTopLevelBufferCount(void *handle)
{
return ((CanTalonSRX*)handle)->GetMotionProfileTopLevelBufferCount();
}
int c_TalonSRX_IsMotionProfileTopLevelBufferFull(void *handle)
{
return ((CanTalonSRX*)handle)->IsMotionProfileTopLevelBufferFull();
}
CTR_Code c_TalonSRX_PushMotionProfileTrajectory(void *handle, int targPos, int targVel, int profileSlotSelect, int timeDurMs, int velOnly, int isLastPoint, int zeroPos)
{
return ((CanTalonSRX*)handle)->PushMotionProfileTrajectory(targPos, targVel, profileSlotSelect, timeDurMs, velOnly, isLastPoint, zeroPos);
}
void c_TalonSRX_ProcessMotionProfileBuffer(void *handle)
{
return ((CanTalonSRX*)handle)->ProcessMotionProfileBuffer();
}
CTR_Code c_TalonSRX_GetMotionProfileStatus(void *handle, int *flags, int *profileSlotSelect, int *targPos, int *targVel, int *topBufferRemaining, int *topBufferCnt, int *btmBufferCnt, int *outputEnable)
{
uint32_t flags_val;
uint32_t profileSlotSelect_val;
int32_t targPos_val;
int32_t targVel_val;
uint32_t topBufferRemaining_val;
uint32_t topBufferCnt_val;
uint32_t btmBufferCnt_val;
uint32_t outputEnable_val;
CTR_Code retval = ((CanTalonSRX*)handle)->GetMotionProfileStatus(flags_val, profileSlotSelect_val, targPos_val, targVel_val, topBufferRemaining_val, topBufferCnt_val, btmBufferCnt_val, outputEnable_val);
*flags = (int)flags_val;
*profileSlotSelect = (int)profileSlotSelect_val;
*targPos = (int)targPos_val;
*targVel = (int)targVel_val;
*topBufferRemaining = (int)topBufferRemaining_val;
*topBufferCnt = (int)topBufferCnt_val;
*btmBufferCnt = (int)btmBufferCnt_val;
*outputEnable = (int)outputEnable_val;
return retval;
}
CTR_Code c_TalonSRX_GetFault_OverTemp(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_OverTemp(*param);
}
CTR_Code c_TalonSRX_GetFault_UnderVoltage(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_UnderVoltage(*param);
}
CTR_Code c_TalonSRX_GetFault_ForLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_ForLim(*param);
}
CTR_Code c_TalonSRX_GetFault_RevLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_RevLim(*param);
}
CTR_Code c_TalonSRX_GetFault_HardwareFailure(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_HardwareFailure(*param);
}
CTR_Code c_TalonSRX_GetFault_ForSoftLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_ForSoftLim(*param);
}
CTR_Code c_TalonSRX_GetFault_RevSoftLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFault_RevSoftLim(*param);
}
CTR_Code c_TalonSRX_GetStckyFault_OverTemp(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetStckyFault_OverTemp(*param);
}
CTR_Code c_TalonSRX_GetStckyFault_UnderVoltage(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetStckyFault_UnderVoltage(*param);
}
CTR_Code c_TalonSRX_GetStckyFault_ForLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetStckyFault_ForLim(*param);
}
CTR_Code c_TalonSRX_GetStckyFault_RevLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetStckyFault_RevLim(*param);
}
CTR_Code c_TalonSRX_GetStckyFault_ForSoftLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetStckyFault_ForSoftLim(*param);
}
CTR_Code c_TalonSRX_GetStckyFault_RevSoftLim(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetStckyFault_RevSoftLim(*param);
}
CTR_Code c_TalonSRX_GetAppliedThrottle(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetAppliedThrottle(*param);
}
CTR_Code c_TalonSRX_GetCloseLoopErr(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetCloseLoopErr(*param);
}
CTR_Code c_TalonSRX_GetFeedbackDeviceSelect(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFeedbackDeviceSelect(*param);
}
CTR_Code c_TalonSRX_GetModeSelect(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetModeSelect(*param);
}
CTR_Code c_TalonSRX_GetLimitSwitchEn(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetLimitSwitchEn(*param);
}
CTR_Code c_TalonSRX_GetLimitSwitchClosedFor(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetLimitSwitchClosedFor(*param);
}
CTR_Code c_TalonSRX_GetLimitSwitchClosedRev(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetLimitSwitchClosedRev(*param);
}
CTR_Code c_TalonSRX_GetSensorPosition(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetSensorPosition(*param);
}
CTR_Code c_TalonSRX_GetSensorVelocity(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetSensorVelocity(*param);
}
CTR_Code c_TalonSRX_GetCurrent(void *handle, double *param)
{
return ((CanTalonSRX*)handle)->GetCurrent(*param);
}
CTR_Code c_TalonSRX_GetBrakeIsEnabled(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetBrakeIsEnabled(*param);
}
CTR_Code c_TalonSRX_GetEncPosition(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetEncPosition(*param);
}
CTR_Code c_TalonSRX_GetEncVel(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetEncVel(*param);
}
CTR_Code c_TalonSRX_GetEncIndexRiseEvents(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetEncIndexRiseEvents(*param);
}
CTR_Code c_TalonSRX_GetQuadApin(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetQuadApin(*param);
}
CTR_Code c_TalonSRX_GetQuadBpin(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetQuadBpin(*param);
}
CTR_Code c_TalonSRX_GetQuadIdxpin(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetQuadIdxpin(*param);
}
CTR_Code c_TalonSRX_GetAnalogInWithOv(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetAnalogInWithOv(*param);
}
CTR_Code c_TalonSRX_GetAnalogInVel(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetAnalogInVel(*param);
}
CTR_Code c_TalonSRX_GetTemp(void *handle, double *param)
{
return ((CanTalonSRX*)handle)->GetTemp(*param);
}
CTR_Code c_TalonSRX_GetBatteryV(void *handle, double *param)
{
return ((CanTalonSRX*)handle)->GetBatteryV(*param);
}
CTR_Code c_TalonSRX_GetResetCount(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetResetCount(*param);
}
CTR_Code c_TalonSRX_GetResetFlags(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetResetFlags(*param);
}
CTR_Code c_TalonSRX_GetFirmVers(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetFirmVers(*param);
}
CTR_Code c_TalonSRX_GetPulseWidthPosition(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetPulseWidthPosition(*param);
}
CTR_Code c_TalonSRX_GetPulseWidthVelocity(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetPulseWidthVelocity(*param);
}
CTR_Code c_TalonSRX_GetPulseWidthRiseToRiseUs(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetPulseWidthRiseToRiseUs(*param);
}
CTR_Code c_TalonSRX_GetActTraj_IsValid(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetActTraj_IsValid(*param);
}
CTR_Code c_TalonSRX_GetActTraj_ProfileSlotSelect(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetActTraj_ProfileSlotSelect(*param);
}
CTR_Code c_TalonSRX_GetActTraj_VelOnly(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetActTraj_VelOnly(*param);
}
CTR_Code c_TalonSRX_GetActTraj_IsLast(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetActTraj_IsLast(*param);
}
CTR_Code c_TalonSRX_GetOutputType(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetOutputType(*param);
}
CTR_Code c_TalonSRX_GetHasUnderrun(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetHasUnderrun(*param);
}
CTR_Code c_TalonSRX_GetIsUnderrun(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetIsUnderrun(*param);
}
CTR_Code c_TalonSRX_GetNextID(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetNextID(*param);
}
CTR_Code c_TalonSRX_GetBufferIsFull(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetBufferIsFull(*param);
}
CTR_Code c_TalonSRX_GetCount(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetCount(*param);
}
CTR_Code c_TalonSRX_GetActTraj_Velocity(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetActTraj_Velocity(*param);
}
CTR_Code c_TalonSRX_GetActTraj_Position(void *handle, int *param)
{
return ((CanTalonSRX*)handle)->GetActTraj_Position(*param);
}
CTR_Code c_TalonSRX_SetDemand(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetDemand(param);
}
CTR_Code c_TalonSRX_SetOverrideLimitSwitchEn(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetOverrideLimitSwitchEn(param);
}
CTR_Code c_TalonSRX_SetFeedbackDeviceSelect(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetFeedbackDeviceSelect(param);
}
CTR_Code c_TalonSRX_SetRevMotDuringCloseLoopEn(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetRevMotDuringCloseLoopEn(param);
}
CTR_Code c_TalonSRX_SetOverrideBrakeType(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetOverrideBrakeType(param);
}
CTR_Code c_TalonSRX_SetModeSelect(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetModeSelect(param);
}
CTR_Code c_TalonSRX_SetProfileSlotSelect(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetProfileSlotSelect(param);
}
CTR_Code c_TalonSRX_SetRampThrottle(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetRampThrottle(param);
}
CTR_Code c_TalonSRX_SetRevFeedbackSensor(void *handle, int param)
{
return ((CanTalonSRX*)handle)->SetRevFeedbackSensor(param);
}
}