Gitiles
Code Review Sign In
realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / cf32412550e07365bb2afb6faed18e0e4c0ff7c1 / . / wpilibc / src / main / native / cpp / PneumaticsControlModule.cpp
blob: 60cd84dcb32b6c7441bc5a6542599a5ea61af80e [file] [log] [blame]
// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.
#include "frc/PneumaticsControlModule.h"
#include <hal/CTREPCM.h>
#include <wpi/NullDeleter.h>
#include <wpi/StackTrace.h>
#include "frc/Compressor.h"
#include "frc/DoubleSolenoid.h"
#include "frc/Errors.h"
#include "frc/SensorUtil.h"
#include "frc/Solenoid.h"
using namespace frc;
wpi::mutex PneumaticsControlModule::m_handleLock;
std::unique_ptr<
wpi::DenseMap<int, std::weak_ptr<PneumaticsControlModule::DataStore>>>
PneumaticsControlModule::m_handleMap = nullptr;
// Always called under lock, so we can avoid the double lock from the magic
// static
std::weak_ptr<PneumaticsControlModule::DataStore>&
PneumaticsControlModule::GetDataStore(int module) {
if (!m_handleMap) {
m_handleMap = std::make_unique<wpi::DenseMap<
int, std::weak_ptr<PneumaticsControlModule::DataStore>>>();
}
return (*m_handleMap)[module];
}
class PneumaticsControlModule::DataStore {
public:
explicit DataStore(int module, const char* stackTrace) {
int32_t status = 0;
HAL_CTREPCMHandle handle =
HAL_InitializeCTREPCM(module, stackTrace, &status);
FRC_CheckErrorStatus(status, "Module {}", module);
m_moduleObject = PneumaticsControlModule{handle, module};
m_moduleObject.m_dataStore =
std::shared_ptr<DataStore>{this, wpi::NullDeleter<DataStore>()};
}
~DataStore() noexcept { HAL_FreeCTREPCM(m_moduleObject.m_handle); }
DataStore(DataStore&&) = delete;
DataStore& operator=(DataStore&&) = delete;
private:
friend class PneumaticsControlModule;
uint32_t m_reservedMask{0};
bool m_compressorReserved{false};
wpi::mutex m_reservedLock;
PneumaticsControlModule m_moduleObject{HAL_kInvalidHandle, 0};
};
PneumaticsControlModule::PneumaticsControlModule()
: PneumaticsControlModule{SensorUtil::GetDefaultCTREPCMModule()} {}
PneumaticsControlModule::PneumaticsControlModule(int module) {
std::string stackTrace = wpi::GetStackTrace(1);
std::scoped_lock lock(m_handleLock);
auto& res = GetDataStore(module);
m_dataStore = res.lock();
if (!m_dataStore) {
m_dataStore = std::make_shared<DataStore>(module, stackTrace.c_str());
res = m_dataStore;
}
m_handle = m_dataStore->m_moduleObject.m_handle;
m_module = module;
}
PneumaticsControlModule::PneumaticsControlModule(HAL_CTREPCMHandle handle,
int module)
: m_handle{handle}, m_module{module} {}
bool PneumaticsControlModule::GetCompressor() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMCompressor(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
void PneumaticsControlModule::DisableCompressor() {
int32_t status = 0;
HAL_SetCTREPCMClosedLoopControl(m_handle, false, &status);
FRC_ReportError(status, "Module {}", m_module);
}
void PneumaticsControlModule::EnableCompressorDigital() {
int32_t status = 0;
HAL_SetCTREPCMClosedLoopControl(m_handle, true, &status);
FRC_ReportError(status, "Module {}", m_module);
}
void PneumaticsControlModule::EnableCompressorAnalog(
units::pounds_per_square_inch_t minPressure,
units::pounds_per_square_inch_t maxPressure) {
int32_t status = 0;
HAL_SetCTREPCMClosedLoopControl(m_handle, true, &status);
FRC_ReportError(status, "Module {}", m_module);
}
void PneumaticsControlModule::EnableCompressorHybrid(
units::pounds_per_square_inch_t minPressure,
units::pounds_per_square_inch_t maxPressure) {
int32_t status = 0;
HAL_SetCTREPCMClosedLoopControl(m_handle, true, &status);
FRC_ReportError(status, "Module {}", m_module);
}
CompressorConfigType PneumaticsControlModule::GetCompressorConfigType() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMClosedLoopControl(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result ? CompressorConfigType::Digital
: CompressorConfigType::Disabled;
}
bool PneumaticsControlModule::GetPressureSwitch() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMPressureSwitch(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
units::ampere_t PneumaticsControlModule::GetCompressorCurrent() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMCompressorCurrent(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return units::ampere_t{result};
}
bool PneumaticsControlModule::GetCompressorCurrentTooHighFault() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMCompressorCurrentTooHighFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetCompressorCurrentTooHighStickyFault() const {
int32_t status = 0;
auto result =
HAL_GetCTREPCMCompressorCurrentTooHighStickyFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetCompressorShortedFault() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMCompressorShortedFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetCompressorShortedStickyFault() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMCompressorShortedStickyFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetCompressorNotConnectedFault() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMCompressorNotConnectedFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetCompressorNotConnectedStickyFault() const {
int32_t status = 0;
auto result =
HAL_GetCTREPCMCompressorNotConnectedStickyFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetSolenoidVoltageFault() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMSolenoidVoltageFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
bool PneumaticsControlModule::GetSolenoidVoltageStickyFault() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMSolenoidVoltageStickyFault(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
void PneumaticsControlModule::ClearAllStickyFaults() {
int32_t status = 0;
HAL_ClearAllCTREPCMStickyFaults(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
}
void PneumaticsControlModule::SetSolenoids(int mask, int values) {
int32_t status = 0;
HAL_SetCTREPCMSolenoids(m_handle, mask, values, &status);
FRC_ReportError(status, "Module {}", m_module);
}
int PneumaticsControlModule::GetSolenoids() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMSolenoids(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
int PneumaticsControlModule::GetModuleNumber() const {
return m_module;
}
int PneumaticsControlModule::GetSolenoidDisabledList() const {
int32_t status = 0;
auto result = HAL_GetCTREPCMSolenoidDisabledList(m_handle, &status);
FRC_ReportError(status, "Module {}", m_module);
return result;
}
void PneumaticsControlModule::FireOneShot(int index) {
int32_t status = 0;
HAL_FireCTREPCMOneShot(m_handle, index, &status);
FRC_ReportError(status, "Module {}", m_module);
}
void PneumaticsControlModule::SetOneShotDuration(int index,
units::second_t duration) {
int32_t status = 0;
units::millisecond_t millis = duration;
HAL_SetCTREPCMOneShotDuration(m_handle, index, millis.to<int32_t>(), &status);
FRC_ReportError(status, "Module {}", m_module);
}
bool PneumaticsControlModule::CheckSolenoidChannel(int channel) const {
return HAL_CheckCTREPCMSolenoidChannel(channel);
}
int PneumaticsControlModule::CheckAndReserveSolenoids(int mask) {
std::scoped_lock lock{m_dataStore->m_reservedLock};
uint32_t uMask = static_cast<uint32_t>(mask);
if ((m_dataStore->m_reservedMask & uMask) != 0) {
return m_dataStore->m_reservedMask & uMask;
}
m_dataStore->m_reservedMask |= uMask;
return 0;
}
void PneumaticsControlModule::UnreserveSolenoids(int mask) {
std::scoped_lock lock{m_dataStore->m_reservedLock};
m_dataStore->m_reservedMask &= ~(static_cast<uint32_t>(mask));
}
bool PneumaticsControlModule::ReserveCompressor() {
std::scoped_lock lock{m_dataStore->m_reservedLock};
if (m_dataStore->m_compressorReserved) {
return false;
}
m_dataStore->m_compressorReserved = true;
return true;
}
void PneumaticsControlModule::UnreserveCompressor() {
std::scoped_lock lock{m_dataStore->m_reservedLock};
m_dataStore->m_compressorReserved = false;
}
units::volt_t PneumaticsControlModule::GetAnalogVoltage(int channel) const {
return units::volt_t{0};
}
units::pounds_per_square_inch_t PneumaticsControlModule::GetPressure(
int channel) const {
return 0_psi;
}
Solenoid PneumaticsControlModule::MakeSolenoid(int channel) {
return Solenoid{m_module, PneumaticsModuleType::CTREPCM, channel};
}
DoubleSolenoid PneumaticsControlModule::MakeDoubleSolenoid(int forwardChannel,
int reverseChannel) {
return DoubleSolenoid{m_module, PneumaticsModuleType::CTREPCM, forwardChannel,
reverseChannel};
}
Compressor PneumaticsControlModule::MakeCompressor() {
return Compressor{m_module, PneumaticsModuleType::CTREPCM};
}
std::shared_ptr<PneumaticsBase> PneumaticsControlModule::GetForModule(
int module) {
std::string stackTrace = wpi::GetStackTrace(1);
std::scoped_lock lock(m_handleLock);
auto& res = GetDataStore(module);
std::shared_ptr<DataStore> dataStore = res.lock();
if (!dataStore) {
dataStore = std::make_shared<DataStore>(module, stackTrace.c_str());
res = dataStore;
}
return std::shared_ptr<PneumaticsBase>{dataStore, &dataStore->m_moduleObject};
}