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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / 4b81d3014e62032c63ff45fefc190fe002faa2bb / . / hal / src / main / native / athena / DigitalInternal.cpp
blob: 205ce3ec1fab9de47f88017a584fb09d7b6be43c [file] [log] [blame]
/*----------------------------------------------------------------------------*/
/* Copyright (c) 2016-2019 FIRST. 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 "DigitalInternal.h"
#include <atomic>
#include <thread>
#include <FRC_NetworkCommunication/LoadOut.h>
#include <wpi/mutex.h>
#include "ConstantsInternal.h"
#include "HALInitializer.h"
#include "PortsInternal.h"
#include "hal/AnalogTrigger.h"
#include "hal/ChipObject.h"
#include "hal/HAL.h"
#include "hal/Ports.h"
#include "hal/cpp/UnsafeDIO.h"
namespace hal {
std::unique_ptr<tDIO> digitalSystem;
std::unique_ptr<tRelay> relaySystem;
std::unique_ptr<tPWM> pwmSystem;
std::unique_ptr<tSPI> spiSystem;
// Create a mutex to protect changes to the digital output values
wpi::mutex digitalDIOMutex;
DigitalHandleResource<HAL_DigitalHandle, DigitalPort,
kNumDigitalChannels + kNumPWMHeaders>*
digitalChannelHandles;
namespace init {
void InitializeDigitalInternal() {
static DigitalHandleResource<HAL_DigitalHandle, DigitalPort,
kNumDigitalChannels + kNumPWMHeaders>
dcH;
digitalChannelHandles = &dcH;
}
} // namespace init
namespace detail {
wpi::mutex& UnsafeGetDIOMutex() { return digitalDIOMutex; }
tDIO* UnsafeGetDigialSystem() { return digitalSystem.get(); }
int32_t ComputeDigitalMask(HAL_DigitalHandle handle, int32_t* status) {
auto port = digitalChannelHandles->Get(handle, HAL_HandleEnum::DIO);
if (port == nullptr) {
*status = HAL_HANDLE_ERROR;
return 0;
}
tDIO::tDO output;
output.value = 0;
if (port->channel >= kNumDigitalHeaders + kNumDigitalMXPChannels) {
output.SPIPort = (1u << remapSPIChannel(port->channel));
} else if (port->channel < kNumDigitalHeaders) {
output.Headers = (1u << port->channel);
} else {
output.MXP = (1u << remapMXPChannel(port->channel));
}
return output.value;
}
} // namespace detail
void initializeDigital(int32_t* status) {
hal::init::CheckInit();
static std::atomic_bool initialized{false};
static wpi::mutex initializeMutex;
// Initial check, as if it's true initialization has finished
if (initialized) return;
std::scoped_lock lock(initializeMutex);
// Second check in case another thread was waiting
if (initialized) return;
digitalSystem.reset(tDIO::create(status));
// Relay Setup
relaySystem.reset(tRelay::create(status));
// Turn off all relay outputs.
relaySystem->writeValue_Forward(0, status);
relaySystem->writeValue_Reverse(0, status);
// PWM Setup
pwmSystem.reset(tPWM::create(status));
// Make sure that the 9403 IONode has had a chance to initialize before
// continuing.
while (pwmSystem->readLoopTiming(status) == 0) std::this_thread::yield();
if (pwmSystem->readLoopTiming(status) != kExpectedLoopTiming) {
*status = LOOP_TIMING_ERROR; // NOTE: Doesn't display the error
}
// Calculate the length, in ms, of one DIO loop
double loopTime = pwmSystem->readLoopTiming(status) /
(kSystemClockTicksPerMicrosecond * 1e3);
pwmSystem->writeConfig_Period(
static_cast<uint16_t>(kDefaultPwmPeriod / loopTime + 0.5), status);
uint16_t minHigh = static_cast<uint16_t>(
(kDefaultPwmCenter - kDefaultPwmStepsDown * loopTime) / loopTime + 0.5);
pwmSystem->writeConfig_MinHigh(minHigh, status);
// Ensure that PWM output values are set to OFF
for (uint8_t pwmIndex = 0; pwmIndex < kNumPWMChannels; pwmIndex++) {
// Copy of SetPWM
if (pwmIndex < tPWM::kNumHdrRegisters) {
pwmSystem->writeHdr(pwmIndex, kPwmDisabled, status);
} else {
pwmSystem->writeMXP(pwmIndex - tPWM::kNumHdrRegisters, kPwmDisabled,
status);
}
// Copy of SetPWMPeriodScale, set to 4x by default.
if (pwmIndex < tPWM::kNumPeriodScaleHdrElements) {
pwmSystem->writePeriodScaleHdr(pwmIndex, 3, status);
} else {
pwmSystem->writePeriodScaleMXP(
pwmIndex - tPWM::kNumPeriodScaleHdrElements, 3, status);
}
}
// SPI setup
spiSystem.reset(tSPI::create(status));
initialized = true;
}
bool remapDigitalSource(HAL_Handle digitalSourceHandle,
HAL_AnalogTriggerType analogTriggerType,
uint8_t& channel, uint8_t& module,
bool& analogTrigger) {
if (isHandleType(digitalSourceHandle, HAL_HandleEnum::AnalogTrigger)) {
// If handle passed, index is not negative
int32_t index = getHandleIndex(digitalSourceHandle);
channel = (index << 2) + analogTriggerType;
module = channel >> 4;
analogTrigger = true;
return true;
} else if (isHandleType(digitalSourceHandle, HAL_HandleEnum::DIO)) {
int32_t index = getHandleIndex(digitalSourceHandle);
if (index >= kNumDigitalHeaders + kNumDigitalMXPChannels) {
// channels 10-15, so need to add headers to remap index
channel = remapSPIChannel(index) + kNumDigitalHeaders;
module = 0;
} else if (index >= kNumDigitalHeaders) {
channel = remapMXPChannel(index);
module = 1;
} else {
channel = index;
module = 0;
}
analogTrigger = false;
return true;
} else {
return false;
}
}
int32_t remapMXPChannel(int32_t channel) { return channel - 10; }
int32_t remapMXPPWMChannel(int32_t channel) {
if (channel < 14) {
return channel - 10; // first block of 4 pwms (MXP 0-3)
} else {
return channel - 6; // block of PWMs after SPI
}
}
int32_t remapSPIChannel(int32_t channel) { return channel - 26; }
} // namespace hal
// Unused function here to test template compile.
__attribute__((unused)) static void CompileFunctorTest() {
hal::UnsafeManipulateDIO(0, nullptr, [](hal::DIOSetProxy& proxy) {});
}