/*----------------------------------------------------------------------------*/ /* Copyright (c) FIRST 2008. All Rights Reserved. */ /* Open Source Software - may be modified and shared by FRC teams. The code */ /* must be accompanied by the FIRST BSD license file in $(WIND_BASE)/WPILib. */ /*----------------------------------------------------------------------------*/ #include "DigitalInput.h" #include "DigitalModule.h" //#include "NetworkCommunication/UsageReporting.h" #include "Resource.h" #include "WPIErrors.h" // TODO: This is not a good place for this... Resource *interruptsResource = NULL; /** * Create an instance of a DigitalInput. * Creates a digital input given a channel. Common creation routine for all * constructors. */ void DigitalInput::InitDigitalInput(uint32_t channel) { m_table = NULL; char buf[64]; Resource::CreateResourceObject(&interruptsResource, interrupt_kNumSystems); if (!CheckDigitalChannel(channel)) { snprintf(buf, 64, "Digital Channel %d", channel); wpi_setWPIErrorWithContext(ChannelIndexOutOfRange, buf); return; } m_channel = channel; m_module = DigitalModule::GetInstance(1); m_module->AllocateDIO(channel, true); HALReport(HALUsageReporting::kResourceType_DigitalInput, channel); } /** * Create an instance of a Digital Input class. * Creates a digital input given a channel. * * @param channel The digital channel (0..19). */ DigitalInput::DigitalInput(uint32_t channel) { InitDigitalInput(channel); } /** * Free resources associated with the Digital Input class. */ DigitalInput::~DigitalInput() { if (StatusIsFatal()) return; if (m_interrupt != NULL) { int32_t status = 0; cleanInterrupts(m_interrupt, &status); wpi_setErrorWithContext(status, getHALErrorMessage(status)); m_interrupt = NULL; interruptsResource->Free(m_interruptIndex); } m_module->FreeDIO(m_channel); } /* * Get the value from a digital input channel. * Retrieve the value of a single digital input channel from the FPGA. */ uint32_t DigitalInput::Get() { if (StatusIsFatal()) return 0; return m_module->GetDIO(m_channel); } /** * @return The GPIO channel number that this object represents. */ uint32_t DigitalInput::GetChannel() { return m_channel; } /** * @return The value to be written to the channel field of a routing mux. */ uint32_t DigitalInput::GetChannelForRouting() { return GetChannel(); } /** * @return The value to be written to the module field of a routing mux. */ uint32_t DigitalInput::GetModuleForRouting() { if (StatusIsFatal()) return 0; return m_module->GetNumber() - 1; } /** * @return The value to be written to the analog trigger field of a routing mux. */ bool DigitalInput::GetAnalogTriggerForRouting() { return false; } /** * Request interrupts asynchronously on this digital input. * @param handler The address of the interrupt handler function of type tInterruptHandler that * will be called whenever there is an interrupt on the digitial input port. * Request interrupts in synchronus mode where the user program interrupt handler will be * called when an interrupt occurs. * The default is interrupt on rising edges only. */ void DigitalInput::RequestInterrupts(InterruptHandlerFunction handler, void *param) { if (StatusIsFatal()) return; uint32_t index = interruptsResource->Allocate("Async Interrupt"); if (index == ~0ul) { CloneError(interruptsResource); return; } m_interruptIndex = index; // Creates a manager too AllocateInterrupts(false); int32_t status = 0; requestInterrupts(m_interrupt, GetModuleForRouting(), GetChannelForRouting(), GetAnalogTriggerForRouting(), &status); SetUpSourceEdge(true, false); attachInterruptHandler(m_interrupt, handler, param, &status); wpi_setErrorWithContext(status, getHALErrorMessage(status)); } /** * Request interrupts synchronously on this digital input. * Request interrupts in synchronus mode where the user program will have to explicitly * wait for the interrupt to occur. * The default is interrupt on rising edges only. */ void DigitalInput::RequestInterrupts() { if (StatusIsFatal()) return; uint32_t index = interruptsResource->Allocate("Sync Interrupt"); if (index == ~0ul) { CloneError(interruptsResource); return; } m_interruptIndex = index; AllocateInterrupts(true); int32_t status = 0; requestInterrupts(m_interrupt, GetModuleForRouting(), GetChannelForRouting(), GetAnalogTriggerForRouting(), &status); wpi_setErrorWithContext(status, getHALErrorMessage(status)); SetUpSourceEdge(true, false); } void DigitalInput::SetUpSourceEdge(bool risingEdge, bool fallingEdge) { if (StatusIsFatal()) return; if (m_interrupt == NULL) { wpi_setWPIErrorWithContext(NullParameter, "You must call RequestInterrupts before SetUpSourceEdge"); return; } if (m_interrupt != NULL) { int32_t status = 0; setInterruptUpSourceEdge(m_interrupt, risingEdge, fallingEdge, &status); wpi_setErrorWithContext(status, getHALErrorMessage(status)); } } void DigitalInput::UpdateTable() { if (m_table != NULL) { m_table->PutBoolean("Value", Get()); } } void DigitalInput::StartLiveWindowMode() { } void DigitalInput::StopLiveWindowMode() { } std::string DigitalInput::GetSmartDashboardType() { return "DigitalInput"; } void DigitalInput::InitTable(ITable *subTable) { m_table = subTable; UpdateTable(); } ITable * DigitalInput::GetTable() { return m_table; }