allwpilib/hal/lib/Athena/Interrupts.cpp

/*----------------------------------------------------------------------------*/
/* Copyright (c) FIRST 2016. 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 the root directory of */
/* the project.                                                               */
/*----------------------------------------------------------------------------*/

#include "HAL/Interrupts.hpp"
#include "ChipObject.h"

extern void remapDigitalSource(bool analogTrigger, uint32_t& pin,
                               uint8_t& module);

struct Interrupt  // FIXME: why is this internal?
{
  tInterrupt* anInterrupt;
  tInterruptManager* manager;
};

extern "C" {

void* initializeInterrupts(uint32_t interruptIndex, bool watcher,
                           int32_t* status) {
  Interrupt* anInterrupt = new Interrupt();
  // Expects the calling leaf class to allocate an interrupt index.
  anInterrupt->anInterrupt = tInterrupt::create(interruptIndex, status);
  anInterrupt->anInterrupt->writeConfig_WaitForAck(false, status);
  anInterrupt->manager = new tInterruptManager(
      (1 << interruptIndex) | (1 << (interruptIndex + 8)), watcher, status);
  return anInterrupt;
}

void cleanInterrupts(void* interrupt_pointer, int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  delete anInterrupt->anInterrupt;
  delete anInterrupt->manager;
  anInterrupt->anInterrupt = NULL;
  anInterrupt->manager = NULL;
}

/**
 * In synchronous mode, wait for the defined interrupt to occur.
 * @param timeout Timeout in seconds
 * @param ignorePrevious If true, ignore interrupts that happened before
 * waitForInterrupt was called.
 * @return The mask of interrupts that fired.
 */
uint32_t waitForInterrupt(void* interrupt_pointer, double timeout,
                          bool ignorePrevious, int32_t* status) {
  uint32_t result;
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;

  result = anInterrupt->manager->watch((int32_t)(timeout * 1e3), ignorePrevious,
                                       status);

  // Don't report a timeout as an error - the return code is enough to tell
  // that a timeout happened.
  if (*status == -NiFpga_Status_IrqTimeout) {
    *status = NiFpga_Status_Success;
  }

  return result;
}

/**
 * Enable interrupts to occur on this input.
 * Interrupts are disabled when the RequestInterrupt call is made. This gives
 * time to do the setup of the other options before starting to field
 * interrupts.
 */
void enableInterrupts(void* interrupt_pointer, int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  anInterrupt->manager->enable(status);
}

/**
 * Disable Interrupts without without deallocating structures.
 */
void disableInterrupts(void* interrupt_pointer, int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  anInterrupt->manager->disable(status);
}

/**
 * Return the timestamp for the rising interrupt that occurred most recently.
 * This is in the same time domain as GetClock().
 * @return Timestamp in seconds since boot.
 */
double readRisingTimestamp(void* interrupt_pointer, int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  uint32_t timestamp = anInterrupt->anInterrupt->readRisingTimeStamp(status);
  return timestamp * 1e-6;
}

/**
* Return the timestamp for the falling interrupt that occurred most recently.
* This is in the same time domain as GetClock().
* @return Timestamp in seconds since boot.
*/
double readFallingTimestamp(void* interrupt_pointer, int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  uint32_t timestamp = anInterrupt->anInterrupt->readFallingTimeStamp(status);
  return timestamp * 1e-6;
}

void requestInterrupts(void* interrupt_pointer, uint8_t routing_module,
                       uint32_t routing_pin, bool routing_analog_trigger,
                       int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  anInterrupt->anInterrupt->writeConfig_WaitForAck(false, status);
  remapDigitalSource(routing_analog_trigger, routing_pin, routing_module);
  anInterrupt->anInterrupt->writeConfig_Source_AnalogTrigger(
      routing_analog_trigger, status);
  anInterrupt->anInterrupt->writeConfig_Source_Channel(routing_pin, status);
  anInterrupt->anInterrupt->writeConfig_Source_Module(routing_module, status);
}

void attachInterruptHandler(void* interrupt_pointer,
                            InterruptHandlerFunction handler, void* param,
                            int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  anInterrupt->manager->registerHandler(handler, param, status);
}

void setInterruptUpSourceEdge(void* interrupt_pointer, bool risingEdge,
                              bool fallingEdge, int32_t* status) {
  Interrupt* anInterrupt = (Interrupt*)interrupt_pointer;
  anInterrupt->anInterrupt->writeConfig_RisingEdge(risingEdge, status);
  anInterrupt->anInterrupt->writeConfig_FallingEdge(fallingEdge, status);
}

}  // extern "C"