tests/fuzz/fuzzer_platform.cpp - third_party/openthread - Git at Google

 /*
  *  Copyright (c) 2017, The OpenThread Authors.
  *  All rights reserved.
  *
  *  Redistribution and use in source and binary forms, with or without
  *  modification, are permitted provided that the following conditions are met:
  *  1. Redistributions of source code must retain the above copyright
  *     notice, this list of conditions and the following disclaimer.
  *  2. Redistributions in binary form must reproduce the above copyright
  *     notice, this list of conditions and the following disclaimer in the
  *     documentation and/or other materials provided with the distribution.
  *  3. Neither the name of the copyright holder nor the
  *     names of its contributors may be used to endorse or promote products
  *     derived from this software without specific prior written permission.
  *
  *  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
  *  AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  *  IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
  *  ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
  *  LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  *  CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  *  SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
  *  INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
  *  CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
  *  ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
  *  POSSIBILITY OF SUCH DAMAGE.
  */

 #include "openthread-core-config.h"

 #include "fuzzer_platform.h"

 #include <string.h>

 #include <openthread/platform/alarm-micro.h>
 #include <openthread/platform/alarm-milli.h>
 #include <openthread/platform/diag.h>
 #include <openthread/platform/entropy.h>
 #include <openthread/platform/logging.h>
 #include <openthread/platform/misc.h>
 #include <openthread/platform/radio.h>
 #include <openthread/platform/settings.h>

 #include "mac/mac_frame.hpp"

 using namespace ot;

 typedef struct AlarmState
 {
     uint32_t fire;
     bool     isRunning;
 } AlarmState;

 enum
 {
     IEEE802154_ACK_LENGTH = 5,

     IEEE802154_FRAME_TYPE_ACK = 2 << 0,
 };

 static uint32_t     sAlarmNow;
 static AlarmState   sAlarmMilli;
 static AlarmState   sAlarmMicro;
 static uint32_t     sRandomState = 1;
 static uint8_t      sRadioTransmitPsdu[OT_RADIO_FRAME_MAX_SIZE];
 static otRadioFrame sRadioTransmitFrame;
 static uint8_t      sRadioAckPsdu[OT_RADIO_FRAME_MAX_SIZE];
 static otRadioFrame sRadioAckFrame;
 static bool         sResetWasRequested = false;
 static otRadioState sRadioState        = OT_RADIO_STATE_DISABLED;

 bool otMacFrameIsAckRequested(const otRadioFrame *aFrame)
 {
     return static_cast<const Mac::Frame *>(aFrame)->GetAckRequest();
 }

 uint8_t otMacFrameGetSequence(const otRadioFrame *aFrame)
 {
     return static_cast<const Mac::Frame *>(aFrame)->GetSequence();
 }

 void FuzzerPlatformInit(void)
 {
     sRandomState = 1;
     sAlarmNow    = 0;
     memset(&sAlarmMilli, 0, sizeof(sAlarmMilli));
     memset(&sAlarmMicro, 0, sizeof(sAlarmMicro));

     sRadioTransmitFrame.mPsdu = sRadioTransmitPsdu;
     sRadioAckFrame.mPsdu      = sRadioAckPsdu;
 }

 void FuzzerPlatformProcess(otInstance *aInstance)
 {
     if (sRadioState == OT_RADIO_STATE_TRANSMIT)
     {
         sRadioState = OT_RADIO_STATE_RECEIVE;

         if (otMacFrameIsAckRequested(&sRadioTransmitFrame))
         {
             sRadioAckFrame.mLength  = IEEE802154_ACK_LENGTH;
             sRadioAckFrame.mPsdu[0] = IEEE802154_FRAME_TYPE_ACK;
             sRadioAckFrame.mPsdu[1] = 0;
             sRadioAckFrame.mPsdu[2] = otMacFrameGetSequence(&sRadioTransmitFrame);
             sRadioAckFrame.mChannel = sRadioTransmitFrame.mChannel;

             otPlatRadioTxDone(aInstance, &sRadioTransmitFrame, &sRadioAckFrame, OT_ERROR_NONE);
         }
         else
         {
             otPlatRadioTxDone(aInstance, &sRadioTransmitFrame, nullptr, OT_ERROR_NONE);
         }
     }

     if (sAlarmMilli.isRunning || sAlarmMicro.isRunning)
     {
         uint32_t fire = UINT32_MAX;

         if (sAlarmMilli.isRunning && fire > sAlarmMilli.fire)
         {
             fire = sAlarmMilli.fire;
         }

         if (sAlarmMicro.isRunning && fire > sAlarmMicro.fire)
         {
             fire = sAlarmMicro.fire;
         }

         sAlarmNow = fire;

         if (sAlarmMilli.isRunning && sAlarmNow >= sAlarmMilli.fire)
         {
             sAlarmMilli.isRunning = false;
             otPlatAlarmMilliFired(aInstance);
         }

 #if OPENTHREAD_CONFIG_PLATFORM_USEC_TIMER_ENABLE
         if (sAlarmMicro.isRunning && sAlarmNow >= sAlarmMicro.fire)
         {
             sAlarmMicro.isRunning = false;
             otPlatAlarmMicroFired(aInstance);
         }
 #endif
     }
 }

 bool FuzzerPlatformResetWasRequested(void)
 {
     return sResetWasRequested;
 }

 uint32_t otPlatAlarmMilliGetNow(void)
 {
     return sAlarmNow / 1000;
 }

 void otPlatAlarmMilliStartAt(otInstance *aInstance, uint32_t aT0, uint32_t aDt)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sAlarmMilli.fire      = (aT0 + aDt) * 1000;
     sAlarmMilli.isRunning = true;
 }

 void otPlatAlarmMilliStop(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sAlarmMilli.isRunning = false;
 }

 uint32_t otPlatAlarmMicroGetNow(void)
 {
     return sAlarmNow;
 }

 void otPlatAlarmMicroStartAt(otInstance *aInstance, uint32_t aT0, uint32_t aDt)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sAlarmMicro.fire      = aT0 + aDt;
     sAlarmMicro.isRunning = true;
 }

 void otPlatAlarmMicroStop(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sAlarmMicro.isRunning = false;
 }

 bool otDiagIsEnabled(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     return false;
 }

 otError otDiagProcessCmd(otInstance *aInstance, uint8_t aArgsLength, char *aArgs[], char *aOutput, size_t aOutputMaxLen)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aArgsLength);
     OT_UNUSED_VARIABLE(aArgs);
     OT_UNUSED_VARIABLE(aOutput);
     OT_UNUSED_VARIABLE(aOutputMaxLen);

     return OT_ERROR_NOT_IMPLEMENTED;
 }

 void otDiagProcessCmdLine(otInstance *aInstance, const char *aString, char *aOutput, size_t aOutputMaxLen)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aString);
     OT_UNUSED_VARIABLE(aOutput);
     OT_UNUSED_VARIABLE(aOutputMaxLen);
 }

 void otPlatReset(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sResetWasRequested = true;
 }

 otPlatResetReason otPlatGetResetReason(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return OT_PLAT_RESET_REASON_POWER_ON;
 }

 void otPlatLog(otLogLevel aLogLevel, otLogRegion aLogRegion, const char *aFormat, ...)
 {
     OT_UNUSED_VARIABLE(aLogLevel);
     OT_UNUSED_VARIABLE(aLogRegion);
     OT_UNUSED_VARIABLE(aFormat);
 }

 void otPlatWakeHost(void)
 {
 }

 void otPlatRadioGetIeeeEui64(otInstance *aInstance, uint8_t *aIeeeEui64)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aIeeeEui64);
 }

 void otPlatRadioSetPanId(otInstance *aInstance, uint16_t aPanId)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aPanId);
 }

 void otPlatRadioSetExtendedAddress(otInstance *aInstance, const otExtAddress *aExtAddr)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aExtAddr);
 }

 void otPlatRadioSetShortAddress(otInstance *aInstance, uint16_t aShortAddress)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aShortAddress);
 }

 void otPlatRadioSetPromiscuous(otInstance *aInstance, bool aEnabled)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aEnabled);
 }

 bool otPlatRadioIsEnabled(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return true;
 }

 otError otPlatRadioEnable(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sRadioState = OT_RADIO_STATE_SLEEP;

     return OT_ERROR_NONE;
 }

 otError otPlatRadioDisable(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sRadioState = OT_RADIO_STATE_DISABLED;

     return OT_ERROR_NONE;
 }

 otError otPlatRadioSleep(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);

     sRadioState = OT_RADIO_STATE_SLEEP;

     return OT_ERROR_NONE;
 }

 otError otPlatRadioReceive(otInstance *aInstance, uint8_t aChannel)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aChannel);

     sRadioState = OT_RADIO_STATE_RECEIVE;

     return OT_ERROR_NONE;
 }

 otError otPlatRadioTransmit(otInstance *aInstance, otRadioFrame *aFrame)
 {
     sRadioState = OT_RADIO_STATE_TRANSMIT;

     otPlatRadioTxStarted(aInstance, aFrame);

     return OT_ERROR_NONE;
 }

 otError otPlatRadioGetTransmitPower(otInstance *aInstance, int8_t *aPower)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aPower);
     return OT_ERROR_NONE;
 }

 otRadioFrame *otPlatRadioGetTransmitBuffer(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return &sRadioTransmitFrame;
 }

 int8_t otPlatRadioGetRssi(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return 0;
 }

 otRadioCaps otPlatRadioGetCaps(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return OT_RADIO_CAPS_NONE;
 }

 bool otPlatRadioGetPromiscuous(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return false;
 }

 void otPlatRadioEnableSrcMatch(otInstance *aInstance, bool aEnable)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aEnable);
 }

 otError otPlatRadioAddSrcMatchShortEntry(otInstance *aInstance, uint16_t aShortAddress)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aShortAddress);
     return OT_ERROR_NONE;
 }

 otError otPlatRadioAddSrcMatchExtEntry(otInstance *aInstance, const otExtAddress *aExtAddress)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aExtAddress);
     return OT_ERROR_NONE;
 }

 otError otPlatRadioClearSrcMatchShortEntry(otInstance *aInstance, uint16_t aShortAddress)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aShortAddress);
     return OT_ERROR_NONE;
 }

 otError otPlatRadioClearSrcMatchExtEntry(otInstance *aInstance, const otExtAddress *aExtAddress)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aExtAddress);
     return OT_ERROR_NONE;
 }

 void otPlatRadioClearSrcMatchShortEntries(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
 }

 void otPlatRadioClearSrcMatchExtEntries(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
 }

 otError otPlatRadioEnergyScan(otInstance *aInstance, uint8_t aScanChannel, uint16_t aScanDuration)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aScanChannel);
     OT_UNUSED_VARIABLE(aScanDuration);
     return OT_ERROR_NOT_IMPLEMENTED;
 }

 otError otPlatRadioSetTransmitPower(otInstance *aInstance, int8_t aPower)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aPower);
     return OT_ERROR_NOT_IMPLEMENTED;
 }

 otError otPlatRadioGetCcaEnergyDetectThreshold(otInstance *aInstance, int8_t *aThreshold)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aThreshold);
     return OT_ERROR_NOT_IMPLEMENTED;
 }

 otError otPlatRadioSetCcaEnergyDetectThreshold(otInstance *aInstance, int8_t aThreshold)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aThreshold);
     return OT_ERROR_NOT_IMPLEMENTED;
 }

 int8_t otPlatRadioGetReceiveSensitivity(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
     return 0;
 }

 otError otPlatEntropyGet(uint8_t *aOutput, uint16_t aOutputLength)
 {
     for (uint16_t length = 0; length < aOutputLength; length++)
     {
         aOutput[length] = (uint8_t)rand();
     }

     return OT_ERROR_NONE;
 }

 void otPlatSettingsInit(otInstance *aInstance, const uint16_t *aSensitiveKeys, uint16_t aSensitiveKeysLength)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aSensitiveKeys);
     OT_UNUSED_VARIABLE(aSensitiveKeysLength);
 }

 void otPlatSettingsDeinit(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
 }

 otError otPlatSettingsGet(otInstance *aInstance, uint16_t aKey, int aIndex, uint8_t *aValue, uint16_t *aValueLength)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aKey);
     OT_UNUSED_VARIABLE(aIndex);
     OT_UNUSED_VARIABLE(aValue);
     OT_UNUSED_VARIABLE(aValueLength);
     return OT_ERROR_NOT_FOUND;
 }

 otError otPlatSettingsSet(otInstance *aInstance, uint16_t aKey, const uint8_t *aValue, uint16_t aValueLength)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aKey);
     OT_UNUSED_VARIABLE(aValue);
     OT_UNUSED_VARIABLE(aValueLength);
     return OT_ERROR_NONE;
 }

 otError otPlatSettingsAdd(otInstance *aInstance, uint16_t aKey, const uint8_t *aValue, uint16_t aValueLength)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aKey);
     OT_UNUSED_VARIABLE(aValue);
     OT_UNUSED_VARIABLE(aValueLength);
     return OT_ERROR_NONE;
 }

 otError otPlatSettingsDelete(otInstance *aInstance, uint16_t aKey, int aIndex)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aKey);
     OT_UNUSED_VARIABLE(aIndex);
     return OT_ERROR_NONE;
 }

 void otPlatSettingsWipe(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
 }

 otError otPlatDiagProcess(otInstance *aInstance,
                           uint8_t     aArgsLength,
                           char *      aArgs[],
                           char *      aOutput,
                           size_t      aOutputMaxLen)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aArgsLength);
     OT_UNUSED_VARIABLE(aArgs);
     OT_UNUSED_VARIABLE(aOutput);
     OT_UNUSED_VARIABLE(aOutputMaxLen);

     return OT_ERROR_INVALID_COMMAND;
 }

 void otPlatDiagModeSet(bool aMode)
 {
     OT_UNUSED_VARIABLE(aMode);
 }

 bool otPlatDiagModeGet(void)
 {
     return false;
 }

 void otPlatDiagChannelSet(uint8_t aChannel)
 {
     OT_UNUSED_VARIABLE(aChannel);
 }

 void otPlatDiagTxPowerSet(int8_t aTxPower)
 {
     OT_UNUSED_VARIABLE(aTxPower);
 }

 void otPlatDiagRadioReceived(otInstance *aInstance, otRadioFrame *aFrame, otError aError)
 {
     OT_UNUSED_VARIABLE(aInstance);
     OT_UNUSED_VARIABLE(aFrame);
     OT_UNUSED_VARIABLE(aError);
 }

 void otPlatDiagAlarmCallback(otInstance *aInstance)
 {
     OT_UNUSED_VARIABLE(aInstance);
 }
	/*
	* Copyright (c) 2017, The OpenThread Authors.
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	* 3. Neither the name of the copyright holder nor the
	* names of its contributors may be used to endorse or promote products
	* derived from this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
	* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
	* POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "openthread-core-config.h"

	#include "fuzzer_platform.h"

	#include <string.h>

	#include <openthread/platform/alarm-micro.h>
	#include <openthread/platform/alarm-milli.h>
	#include <openthread/platform/diag.h>
	#include <openthread/platform/entropy.h>
	#include <openthread/platform/logging.h>
	#include <openthread/platform/misc.h>
	#include <openthread/platform/radio.h>
	#include <openthread/platform/settings.h>

	#include "mac/mac_frame.hpp"

	using namespace ot;

	typedef struct AlarmState
	{
	uint32_t fire;
	bool isRunning;
	} AlarmState;

	enum
	{
	IEEE802154_ACK_LENGTH = 5,

	IEEE802154_FRAME_TYPE_ACK = 2 << 0,
	};

	static uint32_t sAlarmNow;
	static AlarmState sAlarmMilli;
	static AlarmState sAlarmMicro;
	static uint32_t sRandomState = 1;
	static uint8_t sRadioTransmitPsdu[OT_RADIO_FRAME_MAX_SIZE];
	static otRadioFrame sRadioTransmitFrame;
	static uint8_t sRadioAckPsdu[OT_RADIO_FRAME_MAX_SIZE];
	static otRadioFrame sRadioAckFrame;
	static bool sResetWasRequested = false;
	static otRadioState sRadioState = OT_RADIO_STATE_DISABLED;

	bool otMacFrameIsAckRequested(const otRadioFrame *aFrame)
	{
	return static_cast<const Mac::Frame *>(aFrame)->GetAckRequest();
	}

	uint8_t otMacFrameGetSequence(const otRadioFrame *aFrame)
	{
	return static_cast<const Mac::Frame *>(aFrame)->GetSequence();
	}

	void FuzzerPlatformInit(void)
	{
	sRandomState = 1;
	sAlarmNow = 0;
	memset(&sAlarmMilli, 0, sizeof(sAlarmMilli));
	memset(&sAlarmMicro, 0, sizeof(sAlarmMicro));

	sRadioTransmitFrame.mPsdu = sRadioTransmitPsdu;
	sRadioAckFrame.mPsdu = sRadioAckPsdu;
	}

	void FuzzerPlatformProcess(otInstance *aInstance)
	{
	if (sRadioState == OT_RADIO_STATE_TRANSMIT)
	{
	sRadioState = OT_RADIO_STATE_RECEIVE;

	if (otMacFrameIsAckRequested(&sRadioTransmitFrame))
	{
	sRadioAckFrame.mLength = IEEE802154_ACK_LENGTH;
	sRadioAckFrame.mPsdu[0] = IEEE802154_FRAME_TYPE_ACK;
	sRadioAckFrame.mPsdu[1] = 0;
	sRadioAckFrame.mPsdu[2] = otMacFrameGetSequence(&sRadioTransmitFrame);
	sRadioAckFrame.mChannel = sRadioTransmitFrame.mChannel;

	otPlatRadioTxDone(aInstance, &sRadioTransmitFrame, &sRadioAckFrame, OT_ERROR_NONE);
	}
	else
	{
	otPlatRadioTxDone(aInstance, &sRadioTransmitFrame, nullptr, OT_ERROR_NONE);
	}
	}

	if (sAlarmMilli.isRunning \|\| sAlarmMicro.isRunning)
	{
	uint32_t fire = UINT32_MAX;

	if (sAlarmMilli.isRunning && fire > sAlarmMilli.fire)
	{
	fire = sAlarmMilli.fire;
	}

	if (sAlarmMicro.isRunning && fire > sAlarmMicro.fire)
	{
	fire = sAlarmMicro.fire;
	}

	sAlarmNow = fire;

	if (sAlarmMilli.isRunning && sAlarmNow >= sAlarmMilli.fire)
	{
	sAlarmMilli.isRunning = false;
	otPlatAlarmMilliFired(aInstance);
	}

	#if OPENTHREAD_CONFIG_PLATFORM_USEC_TIMER_ENABLE
	if (sAlarmMicro.isRunning && sAlarmNow >= sAlarmMicro.fire)
	{
	sAlarmMicro.isRunning = false;
	otPlatAlarmMicroFired(aInstance);
	}
	#endif
	}
	}

	bool FuzzerPlatformResetWasRequested(void)
	{
	return sResetWasRequested;
	}

	uint32_t otPlatAlarmMilliGetNow(void)
	{
	return sAlarmNow / 1000;
	}

	void otPlatAlarmMilliStartAt(otInstance *aInstance, uint32_t aT0, uint32_t aDt)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sAlarmMilli.fire = (aT0 + aDt) * 1000;
	sAlarmMilli.isRunning = true;
	}

	void otPlatAlarmMilliStop(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sAlarmMilli.isRunning = false;
	}

	uint32_t otPlatAlarmMicroGetNow(void)
	{
	return sAlarmNow;
	}

	void otPlatAlarmMicroStartAt(otInstance *aInstance, uint32_t aT0, uint32_t aDt)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sAlarmMicro.fire = aT0 + aDt;
	sAlarmMicro.isRunning = true;
	}

	void otPlatAlarmMicroStop(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sAlarmMicro.isRunning = false;
	}

	bool otDiagIsEnabled(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	return false;
	}

	otError otDiagProcessCmd(otInstance aInstance, uint8_t aArgsLength, char aArgs[], char *aOutput, size_t aOutputMaxLen)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aArgsLength);
	OT_UNUSED_VARIABLE(aArgs);
	OT_UNUSED_VARIABLE(aOutput);
	OT_UNUSED_VARIABLE(aOutputMaxLen);

	return OT_ERROR_NOT_IMPLEMENTED;
	}

	void otDiagProcessCmdLine(otInstance aInstance, const char aString, char *aOutput, size_t aOutputMaxLen)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aString);
	OT_UNUSED_VARIABLE(aOutput);
	OT_UNUSED_VARIABLE(aOutputMaxLen);
	}

	void otPlatReset(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sResetWasRequested = true;
	}

	otPlatResetReason otPlatGetResetReason(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return OT_PLAT_RESET_REASON_POWER_ON;
	}

	void otPlatLog(otLogLevel aLogLevel, otLogRegion aLogRegion, const char *aFormat, ...)
	{
	OT_UNUSED_VARIABLE(aLogLevel);
	OT_UNUSED_VARIABLE(aLogRegion);
	OT_UNUSED_VARIABLE(aFormat);
	}

	void otPlatWakeHost(void)
	{
	}

	void otPlatRadioGetIeeeEui64(otInstance aInstance, uint8_t aIeeeEui64)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aIeeeEui64);
	}

	void otPlatRadioSetPanId(otInstance *aInstance, uint16_t aPanId)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aPanId);
	}

	void otPlatRadioSetExtendedAddress(otInstance aInstance, const otExtAddress aExtAddr)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aExtAddr);
	}

	void otPlatRadioSetShortAddress(otInstance *aInstance, uint16_t aShortAddress)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aShortAddress);
	}

	void otPlatRadioSetPromiscuous(otInstance *aInstance, bool aEnabled)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aEnabled);
	}

	bool otPlatRadioIsEnabled(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return true;
	}

	otError otPlatRadioEnable(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sRadioState = OT_RADIO_STATE_SLEEP;

	return OT_ERROR_NONE;
	}

	otError otPlatRadioDisable(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sRadioState = OT_RADIO_STATE_DISABLED;

	return OT_ERROR_NONE;
	}

	otError otPlatRadioSleep(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);

	sRadioState = OT_RADIO_STATE_SLEEP;

	return OT_ERROR_NONE;
	}

	otError otPlatRadioReceive(otInstance *aInstance, uint8_t aChannel)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aChannel);

	sRadioState = OT_RADIO_STATE_RECEIVE;

	return OT_ERROR_NONE;
	}

	otError otPlatRadioTransmit(otInstance aInstance, otRadioFrame aFrame)
	{
	sRadioState = OT_RADIO_STATE_TRANSMIT;

	otPlatRadioTxStarted(aInstance, aFrame);

	return OT_ERROR_NONE;
	}

	otError otPlatRadioGetTransmitPower(otInstance aInstance, int8_t aPower)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aPower);
	return OT_ERROR_NONE;
	}

	otRadioFrame otPlatRadioGetTransmitBuffer(otInstance aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return &sRadioTransmitFrame;
	}

	int8_t otPlatRadioGetRssi(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return 0;
	}

	otRadioCaps otPlatRadioGetCaps(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return OT_RADIO_CAPS_NONE;
	}

	bool otPlatRadioGetPromiscuous(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return false;
	}

	void otPlatRadioEnableSrcMatch(otInstance *aInstance, bool aEnable)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aEnable);
	}

	otError otPlatRadioAddSrcMatchShortEntry(otInstance *aInstance, uint16_t aShortAddress)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aShortAddress);
	return OT_ERROR_NONE;
	}

	otError otPlatRadioAddSrcMatchExtEntry(otInstance aInstance, const otExtAddress aExtAddress)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aExtAddress);
	return OT_ERROR_NONE;
	}

	otError otPlatRadioClearSrcMatchShortEntry(otInstance *aInstance, uint16_t aShortAddress)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aShortAddress);
	return OT_ERROR_NONE;
	}

	otError otPlatRadioClearSrcMatchExtEntry(otInstance aInstance, const otExtAddress aExtAddress)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aExtAddress);
	return OT_ERROR_NONE;
	}

	void otPlatRadioClearSrcMatchShortEntries(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	}

	void otPlatRadioClearSrcMatchExtEntries(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	}

	otError otPlatRadioEnergyScan(otInstance *aInstance, uint8_t aScanChannel, uint16_t aScanDuration)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aScanChannel);
	OT_UNUSED_VARIABLE(aScanDuration);
	return OT_ERROR_NOT_IMPLEMENTED;
	}

	otError otPlatRadioSetTransmitPower(otInstance *aInstance, int8_t aPower)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aPower);
	return OT_ERROR_NOT_IMPLEMENTED;
	}

	otError otPlatRadioGetCcaEnergyDetectThreshold(otInstance aInstance, int8_t aThreshold)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aThreshold);
	return OT_ERROR_NOT_IMPLEMENTED;
	}

	otError otPlatRadioSetCcaEnergyDetectThreshold(otInstance *aInstance, int8_t aThreshold)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aThreshold);
	return OT_ERROR_NOT_IMPLEMENTED;
	}

	int8_t otPlatRadioGetReceiveSensitivity(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	return 0;
	}

	otError otPlatEntropyGet(uint8_t *aOutput, uint16_t aOutputLength)
	{
	for (uint16_t length = 0; length < aOutputLength; length++)
	{
	aOutput[length] = (uint8_t)rand();
	}

	return OT_ERROR_NONE;
	}

	void otPlatSettingsInit(otInstance aInstance, const uint16_t aSensitiveKeys, uint16_t aSensitiveKeysLength)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aSensitiveKeys);
	OT_UNUSED_VARIABLE(aSensitiveKeysLength);
	}

	void otPlatSettingsDeinit(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	}

	otError otPlatSettingsGet(otInstance aInstance, uint16_t aKey, int aIndex, uint8_t aValue, uint16_t *aValueLength)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aKey);
	OT_UNUSED_VARIABLE(aIndex);
	OT_UNUSED_VARIABLE(aValue);
	OT_UNUSED_VARIABLE(aValueLength);
	return OT_ERROR_NOT_FOUND;
	}

	otError otPlatSettingsSet(otInstance aInstance, uint16_t aKey, const uint8_t aValue, uint16_t aValueLength)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aKey);
	OT_UNUSED_VARIABLE(aValue);
	OT_UNUSED_VARIABLE(aValueLength);
	return OT_ERROR_NONE;
	}

	otError otPlatSettingsAdd(otInstance aInstance, uint16_t aKey, const uint8_t aValue, uint16_t aValueLength)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aKey);
	OT_UNUSED_VARIABLE(aValue);
	OT_UNUSED_VARIABLE(aValueLength);
	return OT_ERROR_NONE;
	}

	otError otPlatSettingsDelete(otInstance *aInstance, uint16_t aKey, int aIndex)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aKey);
	OT_UNUSED_VARIABLE(aIndex);
	return OT_ERROR_NONE;
	}

	void otPlatSettingsWipe(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	}

	otError otPlatDiagProcess(otInstance *aInstance,
	uint8_t aArgsLength,
	char * aArgs[],
	char * aOutput,
	size_t aOutputMaxLen)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aArgsLength);
	OT_UNUSED_VARIABLE(aArgs);
	OT_UNUSED_VARIABLE(aOutput);
	OT_UNUSED_VARIABLE(aOutputMaxLen);

	return OT_ERROR_INVALID_COMMAND;
	}

	void otPlatDiagModeSet(bool aMode)
	{
	OT_UNUSED_VARIABLE(aMode);
	}

	bool otPlatDiagModeGet(void)
	{
	return false;
	}

	void otPlatDiagChannelSet(uint8_t aChannel)
	{
	OT_UNUSED_VARIABLE(aChannel);
	}

	void otPlatDiagTxPowerSet(int8_t aTxPower)
	{
	OT_UNUSED_VARIABLE(aTxPower);
	}

	void otPlatDiagRadioReceived(otInstance aInstance, otRadioFrame aFrame, otError aError)
	{
	OT_UNUSED_VARIABLE(aInstance);
	OT_UNUSED_VARIABLE(aFrame);
	OT_UNUSED_VARIABLE(aError);
	}

	void otPlatDiagAlarmCallback(otInstance *aInstance)
	{
	OT_UNUSED_VARIABLE(aInstance);
	}