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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / refs/heads/main / . / y2022 / wpilib_interface.cc
blob: 469c93bbbfcdc7acfd1c530d80e1a7a0129d0480 [file] [log] [blame] [edit]
#include <unistd.h>
#include <array>
#include <chrono>
#include <cinttypes>
#include <cmath>
#include <cstdio>
#include <cstring>
#include <functional>
#include <memory>
#include <mutex>
#include <thread>
#include "absl/flags/flag.h"
#include "ctre/phoenix/CANifier.h"
#include "frc971/wpilib/ahal/AnalogInput.h"
#include "frc971/wpilib/ahal/Counter.h"
#include "frc971/wpilib/ahal/DigitalGlitchFilter.h"
#include "frc971/wpilib/ahal/DriverStation.h"
#include "frc971/wpilib/ahal/Encoder.h"
#include "frc971/wpilib/ahal/Servo.h"
#include "frc971/wpilib/ahal/TalonFX.h"
#include "frc971/wpilib/ahal/VictorSP.h"
#undef ERROR
#include "ctre/phoenix6/TalonFX.hpp"
#include "aos/commonmath.h"
#include "aos/events/event_loop.h"
#include "aos/events/shm_event_loop.h"
#include "aos/init.h"
#include "aos/logging/logging.h"
#include "aos/realtime.h"
#include "aos/time/time.h"
#include "aos/util/log_interval.h"
#include "aos/util/phased_loop.h"
#include "aos/util/wrapping_counter.h"
#include "frc971/autonomous/auto_mode_generated.h"
#include "frc971/control_loops/drivetrain/drivetrain_position_generated.h"
#include "frc971/input/robot_state_generated.h"
#include "frc971/queues/gyro_generated.h"
#include "frc971/wpilib/ADIS16448.h"
#include "frc971/wpilib/buffered_pcm.h"
#include "frc971/wpilib/buffered_solenoid.h"
#include "frc971/wpilib/dma.h"
#include "frc971/wpilib/drivetrain_writer.h"
#include "frc971/wpilib/encoder_and_potentiometer.h"
#include "frc971/wpilib/joystick_sender.h"
#include "frc971/wpilib/logging_generated.h"
#include "frc971/wpilib/loop_output_handler.h"
#include "frc971/wpilib/pdp_fetcher.h"
#include "frc971/wpilib/sensor_reader.h"
#include "frc971/wpilib/wpilib_robot_base.h"
#include "y2022/constants.h"
#include "y2022/control_loops/superstructure/led_indicator.h"
#include "y2022/control_loops/superstructure/superstructure_can_position_generated.h"
#include "y2022/control_loops/superstructure/superstructure_output_generated.h"
#include "y2022/control_loops/superstructure/superstructure_position_static.h"
using ::aos::monotonic_clock;
using ::y2022::constants::Values;
namespace superstructure = ::y2022::control_loops::superstructure;
namespace chrono = ::std::chrono;
using std::make_unique;
ABSL_FLAG(bool, can_catapult, false,
"If true, use CAN to control the catapult.");
namespace y2022::wpilib {
namespace {
constexpr double kMaxBringupPower = 12.0;
// TODO(Brian): Fix the interpretation of the result of GetRaw here and in the
// DMA stuff and then removing the * 2.0 in *_translate.
// The low bit is direction.
double drivetrain_velocity_translate(double in) {
return (((1.0 / in) / Values::kDrivetrainCyclesPerRevolution()) *
(2.0 * M_PI)) *
Values::kDrivetrainEncoderRatio() *
control_loops::drivetrain::kWheelRadius;
}
double climber_pot_translate(double voltage) {
return voltage * Values::kClimberPotMetersPerVolt();
}
double flipper_arms_pot_translate(double voltage) {
return voltage * Values::kFlipperArmsPotRadiansPerVolt();
}
double intake_pot_translate(double voltage) {
return voltage * Values::kIntakePotRadiansPerVolt();
}
double turret_pot_translate(double voltage) {
return voltage * Values::kTurretPotRadiansPerVolt();
}
constexpr double kMaxFastEncoderPulsesPerSecond =
std::max({Values::kMaxDrivetrainEncoderPulsesPerSecond(),
Values::kMaxIntakeEncoderPulsesPerSecond()});
static_assert(kMaxFastEncoderPulsesPerSecond <= 1300000,
"fast encoders are too fast");
constexpr double kMaxMediumEncoderPulsesPerSecond =
Values::kMaxTurretEncoderPulsesPerSecond();
static_assert(kMaxMediumEncoderPulsesPerSecond <= 400000,
"medium encoders are too fast");
double catapult_pot_translate(double voltage) {
return voltage * Values::kCatapultPotRatio() *
(3.0 /*turns*/ / 5.0 /*volts*/) * (2 * M_PI /*radians*/);
}
void PrintConfigs(ctre::phoenix6::hardware::TalonFX *talon) {
ctre::phoenix6::configs::TalonFXConfiguration configuration;
ctre::phoenix::StatusCode status =
talon->GetConfigurator().Refresh(configuration);
if (!status.IsOK()) {
AOS_LOG(ERROR, "Failed to get falcon configuration: %s: %s",
status.GetName(), status.GetDescription());
}
AOS_LOG(INFO, "configuration: %s", configuration.ToString().c_str());
}
void WriteConfigs(ctre::phoenix6::hardware::TalonFX *talon,
double stator_current_limit, double supply_current_limit) {
ctre::phoenix6::configs::CurrentLimitsConfigs current_limits;
current_limits.StatorCurrentLimit =
units::current::ampere_t{stator_current_limit};
current_limits.StatorCurrentLimitEnable = true;
current_limits.SupplyCurrentLimit =
units::current::ampere_t{supply_current_limit};
current_limits.SupplyCurrentLimitEnable = true;
ctre::phoenix6::configs::TalonFXConfiguration configuration;
configuration.CurrentLimits = current_limits;
ctre::phoenix::StatusCode status =
talon->GetConfigurator().Apply(configuration);
if (!status.IsOK()) {
AOS_LOG(ERROR, "Failed to set falcon configuration: %s: %s",
status.GetName(), status.GetDescription());
}
PrintConfigs(talon);
}
void Disable(ctre::phoenix6::hardware::TalonFX *talon) {
ctre::phoenix6::controls::DutyCycleOut stop_command(0.0);
stop_command.UpdateFreqHz = 0_Hz;
stop_command.EnableFOC = true;
talon->SetControl(stop_command);
}
} // namespace
// Class to send position messages with sensor readings to our loops.
class SensorReader : public ::frc971::wpilib::SensorReader {
public:
SensorReader(::aos::ShmEventLoop *event_loop,
std::shared_ptr<const Values> values)
: ::frc971::wpilib::SensorReader(event_loop),
values_(std::move(values)),
auto_mode_sender_(
event_loop->MakeSender<::frc971::autonomous::AutonomousMode>(
"/autonomous")),
superstructure_position_sender_(
event_loop->MakeSender<superstructure::PositionStatic>(
"/superstructure")),
drivetrain_position_sender_(
event_loop
->MakeSender<::frc971::control_loops::drivetrain::Position>(
"/drivetrain")),
gyro_sender_(event_loop->MakeSender<::frc971::sensors::GyroReading>(
"/drivetrain")) {
// Set to filter out anything shorter than 1/4 of the minimum pulse width
// we should ever see.
UpdateFastEncoderFilterHz(kMaxFastEncoderPulsesPerSecond);
UpdateMediumEncoderFilterHz(kMaxMediumEncoderPulsesPerSecond);
}
void Start() override {
// TODO(Ravago): Figure out why adding multiple DMA readers results in weird
// behavior
// AddToDMA(&imu_heading_reader_);
AddToDMA(&imu_yaw_rate_reader_);
}
// Auto mode switches.
void set_autonomous_mode(int i, ::std::unique_ptr<frc::DigitalInput> sensor) {
autonomous_modes_.at(i) = ::std::move(sensor);
}
void set_catapult_encoder(::std::unique_ptr<frc::Encoder> encoder) {
medium_encoder_filter_.Add(encoder.get());
catapult_encoder_.set_encoder(::std::move(encoder));
}
void set_catapult_absolute_pwm(
::std::unique_ptr<frc::DigitalInput> absolute_pwm) {
catapult_encoder_.set_absolute_pwm(::std::move(absolute_pwm));
}
void set_catapult_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
catapult_encoder_.set_potentiometer(::std::move(potentiometer));
}
void set_heading_input(::std::unique_ptr<frc::DigitalInput> sensor) {
imu_heading_input_ = ::std::move(sensor);
imu_heading_reader_.set_input(imu_heading_input_.get());
}
void set_yaw_rate_input(::std::unique_ptr<frc::DigitalInput> sensor) {
imu_yaw_rate_input_ = ::std::move(sensor);
imu_yaw_rate_reader_.set_input(imu_yaw_rate_input_.get());
}
void set_catapult_falcon_1(
::std::shared_ptr<ctre::phoenix6::hardware::TalonFX> t1,
::std::shared_ptr<ctre::phoenix6::hardware::TalonFX> t2) {
catapult_falcon_1_can_ = ::std::move(t1);
catapult_falcon_2_can_ = ::std::move(t2);
}
void RunIteration() override {
superstructure_reading_->Set(true);
{
aos::Sender<superstructure::PositionStatic>::StaticBuilder builder =
superstructure_position_sender_.MakeStaticBuilder();
CopyPosition(catapult_encoder_, builder->add_catapult(),
Values::kCatapultEncoderCountsPerRevolution(),
Values::kCatapultEncoderRatio(), catapult_pot_translate,
false, values_->catapult.potentiometer_offset);
CopyPosition(*climber_potentiometer_, builder->add_climber(),
climber_pot_translate, false,
values_->climber.potentiometer_offset);
CopyPosition(*flipper_arm_left_potentiometer_,
builder->add_flipper_arm_left(), flipper_arms_pot_translate,
false, values_->flipper_arm_left.potentiometer_offset);
CopyPosition(*flipper_arm_right_potentiometer_,
builder->add_flipper_arm_right(), flipper_arms_pot_translate,
true, values_->flipper_arm_right.potentiometer_offset);
// Intake
CopyPosition(intake_encoder_front_, builder->add_intake_front(),
Values::kIntakeEncoderCountsPerRevolution(),
Values::kIntakeEncoderRatio(), intake_pot_translate, true,
values_->intake_front.potentiometer_offset);
CopyPosition(intake_encoder_back_, builder->add_intake_back(),
Values::kIntakeEncoderCountsPerRevolution(),
Values::kIntakeEncoderRatio(), intake_pot_translate, true,
values_->intake_back.potentiometer_offset);
CopyPosition(turret_encoder_, builder->add_turret(),
Values::kTurretEncoderCountsPerRevolution(),
Values::kTurretEncoderRatio(), turret_pot_translate, false,
values_->turret.potentiometer_offset);
builder->set_intake_beambreak_front(intake_beambreak_front_->Get());
builder->set_intake_beambreak_back(intake_beambreak_back_->Get());
builder->set_turret_beambreak(turret_beambreak_->Get());
builder.CheckOk(builder.Send());
}
{
auto builder = drivetrain_position_sender_.MakeBuilder();
frc971::control_loops::drivetrain::Position::Builder drivetrain_builder =
builder.MakeBuilder<frc971::control_loops::drivetrain::Position>();
drivetrain_builder.add_left_encoder(
constants::Values::DrivetrainEncoderToMeters(
drivetrain_left_encoder_->GetRaw()));
drivetrain_builder.add_left_speed(
drivetrain_velocity_translate(drivetrain_left_encoder_->GetPeriod()));
drivetrain_builder.add_right_encoder(
-constants::Values::DrivetrainEncoderToMeters(
drivetrain_right_encoder_->GetRaw()));
drivetrain_builder.add_right_speed(-drivetrain_velocity_translate(
drivetrain_right_encoder_->GetPeriod()));
builder.CheckOk(builder.Send(drivetrain_builder.Finish()));
}
{
auto builder = gyro_sender_.MakeBuilder();
::frc971::sensors::GyroReading::Builder gyro_reading_builder =
builder.MakeBuilder<::frc971::sensors::GyroReading>();
// +/- 2000 deg / sec
constexpr double kMaxVelocity = 4000; // degrees / second
constexpr double kVelocityRadiansPerSecond =
kMaxVelocity / 360 * (2.0 * M_PI);
// Only part of the full range is used to prevent being 100% on or off.
constexpr double kScaledRangeLow = 0.1;
constexpr double kScaledRangeHigh = 0.9;
constexpr double kPWMFrequencyHz = 200;
double heading_duty_cycle =
imu_heading_reader_.last_width() * kPWMFrequencyHz;
double velocity_duty_cycle =
imu_yaw_rate_reader_.last_width() * kPWMFrequencyHz;
constexpr double kDutyCycleScale =
1 / (kScaledRangeHigh - kScaledRangeLow);
// scale from 0.1 - 0.9 to 0 - 1
double rescaled_heading_duty_cycle =
(heading_duty_cycle - kScaledRangeLow) * kDutyCycleScale;
double rescaled_velocity_duty_cycle =
(velocity_duty_cycle - kScaledRangeLow) * kDutyCycleScale;
if (!std::isnan(rescaled_heading_duty_cycle)) {
gyro_reading_builder.add_angle(rescaled_heading_duty_cycle *
(2.0 * M_PI));
}
if (!std::isnan(rescaled_velocity_duty_cycle)) {
gyro_reading_builder.add_velocity((rescaled_velocity_duty_cycle - 0.5) *
kVelocityRadiansPerSecond);
}
builder.CheckOk(builder.Send(gyro_reading_builder.Finish()));
}
{
auto builder = auto_mode_sender_.MakeBuilder();
uint32_t mode = 0;
for (size_t i = 0; i < autonomous_modes_.size(); ++i) {
if (autonomous_modes_[i] && autonomous_modes_[i]->Get()) {
mode |= 1 << i;
}
}
auto auto_mode_builder =
builder.MakeBuilder<frc971::autonomous::AutonomousMode>();
auto_mode_builder.add_mode(mode);
builder.CheckOk(builder.Send(auto_mode_builder.Finish()));
}
}
void set_climber_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
climber_potentiometer_ = ::std::move(potentiometer);
}
void set_flipper_arm_left_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
flipper_arm_left_potentiometer_ = ::std::move(potentiometer);
}
void set_flipper_arm_right_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
flipper_arm_right_potentiometer_ = ::std::move(potentiometer);
}
std::shared_ptr<frc::DigitalOutput> superstructure_reading_;
void set_superstructure_reading(
std::shared_ptr<frc::DigitalOutput> superstructure_reading) {
superstructure_reading_ = superstructure_reading;
}
void set_intake_encoder_front(::std::unique_ptr<frc::Encoder> encoder) {
fast_encoder_filter_.Add(encoder.get());
intake_encoder_front_.set_encoder(::std::move(encoder));
}
void set_intake_encoder_back(::std::unique_ptr<frc::Encoder> encoder) {
fast_encoder_filter_.Add(encoder.get());
intake_encoder_back_.set_encoder(::std::move(encoder));
}
void set_intake_front_absolute_pwm(
::std::unique_ptr<frc::DigitalInput> absolute_pwm) {
intake_encoder_front_.set_absolute_pwm(::std::move(absolute_pwm));
}
void set_intake_front_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
intake_encoder_front_.set_potentiometer(::std::move(potentiometer));
}
void set_intake_back_absolute_pwm(
::std::unique_ptr<frc::DigitalInput> absolute_pwm) {
intake_encoder_back_.set_absolute_pwm(::std::move(absolute_pwm));
}
void set_intake_back_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
intake_encoder_back_.set_potentiometer(::std::move(potentiometer));
}
void set_turret_encoder(::std::unique_ptr<frc::Encoder> encoder) {
medium_encoder_filter_.Add(encoder.get());
turret_encoder_.set_encoder(::std::move(encoder));
}
void set_turret_absolute_pwm(
::std::unique_ptr<frc::DigitalInput> absolute_pwm) {
turret_encoder_.set_absolute_pwm(::std::move(absolute_pwm));
}
void set_turret_potentiometer(
::std::unique_ptr<frc::AnalogInput> potentiometer) {
turret_encoder_.set_potentiometer(::std::move(potentiometer));
}
void set_intake_beambreak_front(::std::unique_ptr<frc::DigitalInput> sensor) {
intake_beambreak_front_ = ::std::move(sensor);
}
void set_intake_beambreak_back(::std::unique_ptr<frc::DigitalInput> sensor) {
intake_beambreak_back_ = ::std::move(sensor);
}
void set_turret_beambreak(::std::unique_ptr<frc::DigitalInput> sensor) {
turret_beambreak_ = ::std::move(sensor);
}
private:
std::shared_ptr<const Values> values_;
aos::Sender<frc971::autonomous::AutonomousMode> auto_mode_sender_;
aos::Sender<superstructure::PositionStatic> superstructure_position_sender_;
aos::Sender<frc971::control_loops::drivetrain::Position>
drivetrain_position_sender_;
::aos::Sender<::frc971::sensors::GyroReading> gyro_sender_;
std::array<std::unique_ptr<frc::DigitalInput>, 2> autonomous_modes_;
std::unique_ptr<frc::DigitalInput> intake_beambreak_front_,
intake_beambreak_back_, turret_beambreak_, imu_heading_input_,
imu_yaw_rate_input_;
std::unique_ptr<frc::AnalogInput> climber_potentiometer_,
flipper_arm_right_potentiometer_, flipper_arm_left_potentiometer_;
frc971::wpilib::AbsoluteEncoderAndPotentiometer intake_encoder_front_,
intake_encoder_back_, turret_encoder_, catapult_encoder_;
frc971::wpilib::DMAPulseWidthReader imu_heading_reader_, imu_yaw_rate_reader_;
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> catapult_falcon_1_can_,
catapult_falcon_2_can_;
};
class SuperstructureWriter
: public ::frc971::wpilib::LoopOutputHandler<superstructure::Output> {
public:
SuperstructureWriter(aos::EventLoop *event_loop)
: frc971::wpilib::LoopOutputHandler<superstructure::Output>(
event_loop, "/superstructure"),
catapult_reversal_(make_unique<frc::DigitalOutput>(0)) {}
void set_climber_servo_left(::std::unique_ptr<::frc::Servo> t) {
climber_servo_left_ = ::std::move(t);
}
void set_climber_servo_right(::std::unique_ptr<::frc::Servo> t) {
climber_servo_right_ = ::std::move(t);
}
void set_climber_falcon(std::unique_ptr<frc::TalonFX> t) {
climber_falcon_ = std::move(t);
}
void set_turret_falcon(::std::unique_ptr<::frc::TalonFX> t) {
turret_falcon_ = ::std::move(t);
}
void set_catapult_falcon_1(::std::unique_ptr<::frc::TalonFX> t) {
catapult_falcon_1_ = ::std::move(t);
}
void set_catapult_falcon_1(
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> t1,
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> t2) {
catapult_falcon_1_can_ = ::std::move(t1);
catapult_falcon_2_can_ = ::std::move(t2);
for (auto &falcon : {catapult_falcon_1_can_, catapult_falcon_2_can_}) {
ctre::phoenix6::configs::CurrentLimitsConfigs current_limits;
current_limits.StatorCurrentLimit =
units::current::ampere_t{Values::kIntakeRollerStatorCurrentLimit()};
current_limits.StatorCurrentLimitEnable = true;
current_limits.SupplyCurrentLimit =
units::current::ampere_t{Values::kIntakeRollerSupplyCurrentLimit()};
current_limits.SupplyCurrentLimitEnable = true;
ctre::phoenix6::configs::TalonFXConfiguration configuration;
configuration.CurrentLimits = current_limits;
ctre::phoenix::StatusCode status =
falcon->GetConfigurator().Apply(configuration);
if (!status.IsOK()) {
AOS_LOG(ERROR, "Failed to set falcon configuration: %s: %s",
status.GetName(), status.GetDescription());
}
PrintConfigs(falcon.get());
// TODO(max): Figure out how to migrate these configs to phoenix6
/*falcon->SetStatusFramePeriod(
ctre::phoenix::motorcontrol::Status_1_General, 1);
falcon->SetStatusFramePeriod(
ctre::phoenix::motorcontrol::Status_Brushless_Current, 50);
falcon->ConfigOpenloopRamp(0.0);
falcon->ConfigClosedloopRamp(0.0);
falcon->ConfigVoltageMeasurementFilter(1);*/
}
}
void set_intake_falcon_front(::std::unique_ptr<frc::TalonFX> t) {
intake_falcon_front_ = ::std::move(t);
}
void set_intake_falcon_back(::std::unique_ptr<frc::TalonFX> t) {
intake_falcon_back_ = ::std::move(t);
}
void set_roller_falcon_front(
::std::unique_ptr<::ctre::phoenix6::hardware::TalonFX> t) {
roller_falcon_front_ = ::std::move(t);
WriteConfigs(roller_falcon_front_.get(),
Values::kIntakeRollerStatorCurrentLimit(),
Values::kIntakeRollerSupplyCurrentLimit());
}
void set_roller_falcon_back(
::std::unique_ptr<::ctre::phoenix6::hardware::TalonFX> t) {
roller_falcon_back_ = ::std::move(t);
WriteConfigs(roller_falcon_back_.get(),
Values::kIntakeRollerStatorCurrentLimit(),
Values::kIntakeRollerSupplyCurrentLimit());
}
void set_flipper_arms_falcon(
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> t) {
flipper_arms_falcon_ = t;
WriteConfigs(flipper_arms_falcon_.get(),
Values::kFlipperArmSupplyCurrentLimit(),
Values::kFlipperArmStatorCurrentLimit());
}
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> flipper_arms_falcon() {
return flipper_arms_falcon_;
}
void set_transfer_roller_victor(::std::unique_ptr<::frc::VictorSP> t) {
transfer_roller_victor_ = ::std::move(t);
}
std::shared_ptr<frc::DigitalOutput> superstructure_reading_;
void set_superstructure_reading(
std::shared_ptr<frc::DigitalOutput> superstructure_reading) {
superstructure_reading_ = superstructure_reading;
}
private:
void Stop() override {
AOS_LOG(WARNING, "Superstructure output too old.\n");
climber_falcon_->SetDisabled();
climber_servo_left_->SetRaw(0);
climber_servo_right_->SetRaw(0);
Disable(roller_falcon_front_.get());
Disable(roller_falcon_back_.get());
Disable(flipper_arms_falcon_.get());
intake_falcon_front_->SetDisabled();
intake_falcon_back_->SetDisabled();
transfer_roller_victor_->SetDisabled();
if (catapult_falcon_1_) {
catapult_falcon_1_->SetDisabled();
}
if (catapult_falcon_1_can_) {
Disable(catapult_falcon_1_can_.get());
Disable(catapult_falcon_2_can_.get());
}
turret_falcon_->SetDisabled();
}
void Write(const superstructure::Output &output) override {
WritePwm(-output.climber_voltage(), climber_falcon_.get());
climber_servo_left_->SetPosition(output.climber_servo_left());
climber_servo_right_->SetPosition(output.climber_servo_right());
WritePwm(output.intake_voltage_front(), intake_falcon_front_.get());
WritePwm(output.intake_voltage_back(), intake_falcon_back_.get());
WriteCan(output.roller_voltage_front(), roller_falcon_front_.get());
WriteCan(output.roller_voltage_back(), roller_falcon_back_.get());
WritePwm(output.transfer_roller_voltage(), transfer_roller_victor_.get());
WriteCan(-output.flipper_arms_voltage(), flipper_arms_falcon_.get());
if (catapult_falcon_1_) {
WritePwm(output.catapult_voltage(), catapult_falcon_1_.get());
superstructure_reading_->Set(false);
if (output.catapult_voltage() > 0) {
catapult_reversal_->Set(true);
} else {
catapult_reversal_->Set(false);
}
}
if (catapult_falcon_1_can_) {
WriteCanCatapult(output.catapult_voltage(), catapult_falcon_1_can_.get());
WriteCanCatapult(output.catapult_voltage(), catapult_falcon_2_can_.get());
}
WritePwm(-output.turret_voltage(), turret_falcon_.get());
}
static void WriteCan(const double voltage,
::ctre::phoenix6::hardware::TalonFX *falcon) {
ctre::phoenix6::controls::DutyCycleOut control(
std::clamp(voltage, -kMaxBringupPower, kMaxBringupPower) / 12.0);
control.UpdateFreqHz = 0_Hz;
control.EnableFOC = true;
falcon->SetControl(control);
}
// We do this to set our UpdateFreqHz higher
static void WriteCanCatapult(const double voltage,
::ctre::phoenix6::hardware::TalonFX *falcon) {
ctre::phoenix6::controls::DutyCycleOut control(
std::clamp(voltage, -kMaxBringupPower, kMaxBringupPower) / 12.0);
control.UpdateFreqHz = 1000_Hz;
control.EnableFOC = true;
falcon->SetControl(control);
}
template <typename T>
static void WritePwm(const double voltage, T *motor) {
motor->SetSpeed(std::clamp(voltage, -kMaxBringupPower, kMaxBringupPower) /
12.0);
}
::std::unique_ptr<frc::TalonFX> intake_falcon_front_, intake_falcon_back_;
::std::unique_ptr<::ctre::phoenix6::hardware::TalonFX> roller_falcon_front_,
roller_falcon_back_;
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> flipper_arms_falcon_;
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> catapult_falcon_1_can_,
catapult_falcon_2_can_;
::std::unique_ptr<::frc::TalonFX> turret_falcon_, catapult_falcon_1_,
climber_falcon_;
::std::unique_ptr<::frc::VictorSP> transfer_roller_victor_;
std::unique_ptr<frc::DigitalOutput> catapult_reversal_;
::std::unique_ptr<::frc::Servo> climber_servo_left_, climber_servo_right_;
};
class CANSensorReader {
public:
CANSensorReader(aos::EventLoop *event_loop)
: event_loop_(event_loop),
can_position_sender_(
event_loop->MakeSender<superstructure::CANPosition>(
"/superstructure")) {
event_loop->SetRuntimeRealtimePriority(16);
phased_loop_handler_ =
event_loop_->AddPhasedLoop([this](int) { Loop(); }, kPeriod);
phased_loop_handler_->set_name("CAN SensorReader Loop");
event_loop->OnRun([this]() { Loop(); });
}
void set_flipper_arms_falcon(
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> t) {
flipper_arms_falcon_ = std::move(t);
}
private:
void Loop() {
auto builder = can_position_sender_.MakeBuilder();
superstructure::CANPosition::Builder can_position_builder =
builder.MakeBuilder<superstructure::CANPosition>();
can_position_builder.add_flipper_arm_integrated_sensor_velocity(
flipper_arms_falcon_->GetVelocity().GetValue().value() *
kVelocityConversion);
builder.CheckOk(builder.Send(can_position_builder.Finish()));
}
static constexpr std::chrono::milliseconds kPeriod =
std::chrono::milliseconds(20);
// 2048 encoder counts / 100 ms to rad/sec
static constexpr double kVelocityConversion = (2.0 * M_PI / 2048) * 0.100;
aos::EventLoop *event_loop_;
::aos::PhasedLoopHandler *phased_loop_handler_;
::std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> flipper_arms_falcon_;
aos::Sender<superstructure::CANPosition> can_position_sender_;
};
class WPILibRobot : public ::frc971::wpilib::WPILibRobotBase {
public:
::std::unique_ptr<frc::Encoder> make_encoder(int index) {
return make_unique<frc::Encoder>(10 + index * 2, 11 + index * 2, false,
frc::Encoder::k4X);
}
void Run() override {
std::shared_ptr<const Values> values =
std::make_shared<const Values>(constants::MakeValues());
aos::FlatbufferDetachedBuffer<aos::Configuration> config =
aos::configuration::ReadConfig("aos_config.json");
// Thread 1.
::aos::ShmEventLoop joystick_sender_event_loop(&config.message());
::frc971::wpilib::JoystickSender joystick_sender(
&joystick_sender_event_loop);
AddLoop(&joystick_sender_event_loop);
// Thread 2.
::aos::ShmEventLoop pdp_fetcher_event_loop(&config.message());
::frc971::wpilib::PDPFetcher pdp_fetcher(&pdp_fetcher_event_loop);
AddLoop(&pdp_fetcher_event_loop);
std::shared_ptr<frc::DigitalOutput> superstructure_reading =
make_unique<frc::DigitalOutput>(25);
// Thread 3.
::aos::ShmEventLoop sensor_reader_event_loop(&config.message());
SensorReader sensor_reader(&sensor_reader_event_loop, values);
sensor_reader.set_pwm_trigger(true);
sensor_reader.set_drivetrain_left_encoder(make_encoder(1));
sensor_reader.set_drivetrain_right_encoder(make_encoder(0));
sensor_reader.set_superstructure_reading(superstructure_reading);
sensor_reader.set_intake_encoder_front(make_encoder(3));
sensor_reader.set_intake_front_absolute_pwm(
make_unique<frc::DigitalInput>(3));
sensor_reader.set_intake_front_potentiometer(
make_unique<frc::AnalogInput>(3));
sensor_reader.set_intake_encoder_back(make_encoder(4));
sensor_reader.set_intake_back_absolute_pwm(
make_unique<frc::DigitalInput>(4));
sensor_reader.set_intake_back_potentiometer(
make_unique<frc::AnalogInput>(4));
sensor_reader.set_turret_encoder(make_encoder(5));
sensor_reader.set_turret_absolute_pwm(make_unique<frc::DigitalInput>(5));
sensor_reader.set_turret_potentiometer(make_unique<frc::AnalogInput>(5));
// TODO(milind): correct intake beambreak ports once set
sensor_reader.set_intake_beambreak_front(make_unique<frc::DigitalInput>(1));
sensor_reader.set_intake_beambreak_back(make_unique<frc::DigitalInput>(6));
sensor_reader.set_turret_beambreak(make_unique<frc::DigitalInput>(7));
sensor_reader.set_climber_potentiometer(make_unique<frc::AnalogInput>(7));
sensor_reader.set_flipper_arm_left_potentiometer(
make_unique<frc::AnalogInput>(0));
sensor_reader.set_flipper_arm_right_potentiometer(
make_unique<frc::AnalogInput>(1));
// TODO(milind): correct catapult encoder and absolute pwm ports
sensor_reader.set_catapult_encoder(make_encoder(2));
sensor_reader.set_catapult_absolute_pwm(
std::make_unique<frc::DigitalInput>(2));
sensor_reader.set_catapult_potentiometer(
std::make_unique<frc::AnalogInput>(2));
sensor_reader.set_heading_input(make_unique<frc::DigitalInput>(9));
sensor_reader.set_yaw_rate_input(make_unique<frc::DigitalInput>(8));
AddLoop(&sensor_reader_event_loop);
// Thread 4.
::aos::ShmEventLoop output_event_loop(&config.message());
::frc971::wpilib::DrivetrainWriter drivetrain_writer(&output_event_loop);
drivetrain_writer.set_left_controller0(
::std::unique_ptr<::frc::VictorSP>(new ::frc::VictorSP(0)), false);
drivetrain_writer.set_right_controller0(
::std::unique_ptr<::frc::VictorSP>(new ::frc::VictorSP(1)), true);
SuperstructureWriter superstructure_writer(&output_event_loop);
superstructure_writer.set_turret_falcon(make_unique<::frc::TalonFX>(3));
superstructure_writer.set_roller_falcon_front(
make_unique<::ctre::phoenix6::hardware::TalonFX>(0));
superstructure_writer.set_roller_falcon_back(
make_unique<::ctre::phoenix6::hardware::TalonFX>(1));
superstructure_writer.set_transfer_roller_victor(
make_unique<::frc::VictorSP>(5));
superstructure_writer.set_intake_falcon_front(make_unique<frc::TalonFX>(2));
superstructure_writer.set_intake_falcon_back(make_unique<frc::TalonFX>(4));
superstructure_writer.set_climber_falcon(make_unique<frc::TalonFX>(8));
superstructure_writer.set_climber_servo_left(make_unique<frc::Servo>(7));
superstructure_writer.set_climber_servo_right(make_unique<frc::Servo>(6));
superstructure_writer.set_flipper_arms_falcon(
make_unique<::ctre::phoenix6::hardware::TalonFX>(2));
superstructure_writer.set_superstructure_reading(superstructure_reading);
if (!absl::GetFlag(FLAGS_can_catapult)) {
superstructure_writer.set_catapult_falcon_1(make_unique<frc::TalonFX>(9));
} else {
std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> catapult1 =
make_unique<::ctre::phoenix6::hardware::TalonFX>(3, "Catapult");
std::shared_ptr<::ctre::phoenix6::hardware::TalonFX> catapult2 =
make_unique<::ctre::phoenix6::hardware::TalonFX>(4, "Catapult");
superstructure_writer.set_catapult_falcon_1(catapult1, catapult2);
sensor_reader.set_catapult_falcon_1(catapult1, catapult2);
}
AddLoop(&output_event_loop);
// Thread 5.
::aos::ShmEventLoop led_indicator_event_loop(&config.message());
control_loops::superstructure::LedIndicator led_indicator(
&led_indicator_event_loop);
AddLoop(&led_indicator_event_loop);
RunLoops();
}
};
} // namespace y2022::wpilib
AOS_ROBOT_CLASS(::y2022::wpilib::WPILibRobot);