/* * SPDX-FileCopyrightText: 2021-2022 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #include "esp_openthread_radio.h" #include "error.h" #include "esp_err.h" #include "sdkconfig.h" #include "esp_check.h" #include "esp_ieee802154.h" #include "esp_ieee802154_types.h" #include "esp_mac.h" #include "esp_openthread_common_macro.h" #include "esp_openthread_platform.h" #include "esp_openthread_types.h" #include "esp_random.h" #include "esp_system.h" #include "esp_timer.h" #include "esp_vfs.h" #include "esp_vfs_eventfd.h" #include "rom/ets_sys.h" #include "openthread-core-config.h" #include "openthread/link.h" #include "openthread/platform/diag.h" #include "openthread/platform/radio.h" #include "openthread/platform/time.h" #include "utils/link_metrics.h" #include "utils/mac_frame.h" #define ESP_RECEIVE_SENSITIVITY -120 #define ESP_OPENTHREAD_XTAL_ACCURACY 130 #define ESP_OPENTHREAD_CSL_ACCURACY 1 #define ESP_OPENTHREAD_CSL_UNCERTAIN 1 #define EVENT_TX_DONE (1 << 0) #define EVENT_TX_FAILED (1 << 1) #define EVENT_RX_DONE (1 << 2) #define EVENT_ENERGY_DETECT_DONE (1 << 3) typedef struct { uint8_t length; uint8_t psdu[OT_RADIO_FRAME_MAX_SIZE]; } esp_openthread_radio_tx_psdu; typedef struct { uint8_t head; uint8_t tail; uint8_t used; } esp_openthread_circular_queue_info_t; static otRadioFrame s_transmit_frame; static esp_openthread_radio_tx_psdu s_transmit_psdu; static uint8_t *s_enhack; static otRadioFrame s_receive_frame[CONFIG_IEEE802154_RX_BUFFER_SIZE]; static otRadioFrame s_ack_frame; static int s_ed_power; static esp_ieee802154_tx_error_t s_tx_error; static int s_radio_event_fd = -1; static bool s_diag_mode = false; static const char *s_radio_workflow = "radio"; static uint8_t s_txrx_events; #if OPENTHREAD_CONFIG_MAC_HEADER_IE_SUPPORT static otRadioIeInfo s_transmit_ie_info; #endif // OPENTHREAD_CONFIG_MAC_HEADER_IE_SUPPORT #if OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE static uint32_t s_csl_period; static uint32_t s_csl_sample_time; #endif // OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE #if OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 static uint32_t s_mac_frame_counter; static uint8_t s_key_id; static struct otMacKeyMaterial s_pervious_key; static struct otMacKeyMaterial s_current_key; static struct otMacKeyMaterial s_next_key; static bool s_with_security_enh_ack = false; static uint32_t s_ack_frame_counter; static uint8_t s_ack_key_id; static uint8_t s_security_key[16]; static uint8_t s_security_addr[8]; #endif // OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 static esp_openthread_circular_queue_info_t s_recv_queue = {.head = 0, .tail = 0, .used = 0}; static void set_event(uint8_t event) { uint64_t event_write = event; s_txrx_events |= event; int ret = write(s_radio_event_fd, &event_write, sizeof(event_write)); assert(ret == sizeof(event_write)); } static inline void clr_event(uint8_t event) { s_txrx_events &= ~event; } static inline bool get_event(uint8_t event) { return s_txrx_events & event; } esp_err_t esp_openthread_radio_init(const esp_openthread_platform_config_t *config) { ESP_RETURN_ON_FALSE(s_radio_event_fd == -1, ESP_ERR_INVALID_STATE, OT_PLAT_LOG_TAG, "Radio was initalized already!"); s_radio_event_fd = eventfd(0, EFD_SUPPORT_ISR); s_transmit_frame.mPsdu = s_transmit_psdu.psdu; for (uint8_t i = 0; i < CONFIG_IEEE802154_RX_BUFFER_SIZE; i++) { s_receive_frame[i].mPsdu = NULL; } s_ack_frame.mPsdu = NULL; memset(&s_recv_queue, 0, sizeof(esp_openthread_circular_queue_info_t)); #if OPENTHREAD_CONFIG_MAC_HEADER_IE_SUPPORT s_transmit_frame.mInfo.mTxInfo.mIeInfo = &s_transmit_ie_info; #endif esp_ieee802154_enable(); esp_ieee802154_set_promiscuous(false); esp_ieee802154_set_rx_when_idle(true); return esp_openthread_platform_workflow_register(&esp_openthread_radio_update, &esp_openthread_radio_process, s_radio_workflow); } void esp_openthread_radio_deinit(void) { if (s_radio_event_fd > 0) { close(s_radio_event_fd); s_radio_event_fd = -1; } esp_ieee802154_disable(); esp_openthread_platform_workflow_unregister(s_radio_workflow); } void esp_openthread_radio_update(esp_openthread_mainloop_context_t *mainloop) { FD_SET(s_radio_event_fd, &mainloop->read_fds); if (s_radio_event_fd > mainloop->max_fd) { mainloop->max_fd = s_radio_event_fd; } } esp_err_t esp_openthread_radio_process(otInstance *aInstance, const esp_openthread_mainloop_context_t *mainloop) { uint64_t event_read; int ret = read(s_radio_event_fd, &event_read, sizeof(event_read)); assert(ret == sizeof(event_read)); if (get_event(EVENT_TX_DONE)) { clr_event(EVENT_TX_DONE); #if OPENTHREAD_CONFIG_DIAG_ENABLE if (otPlatDiagModeGet()) { otPlatDiagRadioTransmitDone(aInstance, &s_transmit_frame, OT_ERROR_NONE); } else #endif { if (s_ack_frame.mPsdu == NULL) { otPlatRadioTxDone(aInstance, &s_transmit_frame, NULL, OT_ERROR_NONE); } else { otPlatRadioTxDone(aInstance, &s_transmit_frame, &s_ack_frame, OT_ERROR_NONE); s_ack_frame.mPsdu = NULL; } } } if (get_event(EVENT_TX_FAILED)) { clr_event(EVENT_TX_FAILED); #if OPENTHREAD_CONFIG_DIAG_ENABLE if (otPlatDiagModeGet()) { otPlatDiagRadioTransmitDone(aInstance, &s_transmit_frame, OT_ERROR_CHANNEL_ACCESS_FAILURE); } else #endif { otError err = OT_ERROR_NONE; switch (s_tx_error) { case ESP_IEEE802154_TX_ERR_CCA_BUSY: case ESP_IEEE802154_TX_ERR_ABORT: case ESP_IEEE802154_TX_ERR_COEXIST: err = OT_ERROR_CHANNEL_ACCESS_FAILURE; break; case ESP_IEEE802154_TX_ERR_NO_ACK: case ESP_IEEE802154_TX_ERR_INVALID_ACK: err = OT_ERROR_NO_ACK; break; default: ETS_ASSERT(false); break; } otPlatRadioTxDone(aInstance, &s_transmit_frame, NULL, err); } } if (get_event(EVENT_ENERGY_DETECT_DONE)) { clr_event(EVENT_ENERGY_DETECT_DONE); otPlatRadioEnergyScanDone(aInstance, s_ed_power); } while (s_recv_queue.used) { if (s_receive_frame[s_recv_queue.head].mPsdu != NULL) { #if OPENTHREAD_CONFIG_DIAG_ENABLE if (otPlatDiagModeGet()) { otPlatDiagRadioReceiveDone(aInstance, &s_receive_frame[s_recv_queue.head], OT_ERROR_NONE); } else #endif { otPlatRadioReceiveDone(aInstance, &s_receive_frame[s_recv_queue.head], OT_ERROR_NONE); } s_receive_frame[s_recv_queue.head].mPsdu = NULL; s_recv_queue.head = (s_recv_queue.head + 1) % CONFIG_IEEE802154_RX_BUFFER_SIZE; s_recv_queue.used--; } } return ESP_OK; } void otPlatRadioGetIeeeEui64(otInstance *aInstance, uint8_t *aIeeeEui64) { uint8_t eui64[8] = {0}; esp_read_mac(eui64, ESP_MAC_IEEE802154); memcpy(aIeeeEui64, eui64, sizeof(eui64)); } void otPlatRadioSetPanId(otInstance *aInstance, uint16_t panid) { esp_ieee802154_set_panid(panid); } void otPlatRadioSetExtendedAddress(otInstance *aInstance, const otExtAddress *aAddress) { esp_ieee802154_set_extended_address(aAddress->m8); } void otPlatRadioSetShortAddress(otInstance *aInstance, uint16_t aAddress) { esp_ieee802154_set_short_address(aAddress); } void otPlatRadioSetPromiscuous(otInstance *aInstance, bool aEnable) { esp_ieee802154_set_promiscuous(aEnable); } bool otPlatRadioIsEnabled(otInstance *aInstance) { return esp_ieee802154_get_state() != ESP_IEEE802154_RADIO_DISABLE; } otError otPlatRadioEnable(otInstance *aInstance) { // radio has been enabled in esp_openthread_radio_init() return OT_ERROR_NONE; } otError otPlatRadioDisable(otInstance *aInstance) { esp_ieee802154_disable(); return OT_ERROR_NONE; } otError otPlatRadioSleep(otInstance *aInstance) { esp_ieee802154_sleep(); return OT_ERROR_NONE; } otError otPlatRadioReceive(otInstance *aInstance, uint8_t aChannel) { esp_ieee802154_set_channel(aChannel); esp_ieee802154_receive(); return OT_ERROR_NONE; } otError otPlatRadioTransmit(otInstance *aInstance, otRadioFrame *aFrame) { esp_ieee802154_set_channel(aFrame->mChannel); aFrame->mPsdu[-1] = aFrame->mLength; // lenth locates one byte before the psdu (esp_openthread_radio_tx_psdu); if (otMacFrameIsSecurityEnabled(aFrame) && !aFrame->mInfo.mTxInfo.mIsSecurityProcessed) { if (!s_transmit_frame.mInfo.mTxInfo.mIsARetx) { otMacFrameSetFrameCounter(aFrame, s_mac_frame_counter++); } if (otMacFrameIsKeyIdMode1(aFrame)) { s_transmit_frame.mInfo.mTxInfo.mAesKey = &s_current_key; if (!s_transmit_frame.mInfo.mTxInfo.mIsARetx) { otMacFrameSetKeyId(aFrame, s_key_id); } esp_ieee802154_get_extended_address(s_security_addr); } memcpy(s_security_key, s_current_key.mKeyMaterial.mKey.m8, sizeof(s_current_key.mKeyMaterial.mKey.m8)); esp_ieee802154_set_transmit_security(&aFrame->mPsdu[-1], s_security_key, s_security_addr); } if (aFrame->mInfo.mTxInfo.mTxDelay != 0) { esp_ieee802154_transmit_at(&aFrame->mPsdu[-1], aFrame->mInfo.mTxInfo.mCsmaCaEnabled, (aFrame->mInfo.mTxInfo.mTxDelayBaseTime + aFrame->mInfo.mTxInfo.mTxDelay)); } else { esp_ieee802154_transmit(&aFrame->mPsdu[-1], aFrame->mInfo.mTxInfo.mCsmaCaEnabled); } otPlatRadioTxStarted(aInstance, aFrame); return OT_ERROR_NONE; } otRadioFrame *otPlatRadioGetTransmitBuffer(otInstance *aInstance) { return &s_transmit_frame; } int8_t otPlatRadioGetRssi(otInstance *aInstance) { return esp_ieee802154_get_recent_rssi(); } otRadioCaps otPlatRadioGetCaps(otInstance *aInstance) { return (otRadioCaps)(OT_RADIO_CAPS_ENERGY_SCAN | OT_RADIO_CAPS_TRANSMIT_SEC | OT_RADIO_CAPS_RECEIVE_TIMING | OT_RADIO_CAPS_TRANSMIT_TIMING | OT_RADIO_CAPS_ACK_TIMEOUT | OT_RADIO_CAPS_SLEEP_TO_TX); } otError otPlatRadioReceiveAt(otInstance *aInstance, uint8_t aChannel, uint32_t aStart, uint32_t aDuration) { esp_ieee802154_receive_at((aStart + aDuration)); return OT_ERROR_NONE; } bool otPlatRadioGetPromiscuous(otInstance *aInstance) { return esp_ieee802154_get_promiscuous(); } void otPlatRadioEnableSrcMatch(otInstance *aInstance, bool aEnable) { #if OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 esp_ieee802154_set_pending_mode(ESP_IEEE802154_AUTO_PENDING_ENHANCED); #else esp_ieee802154_set_pending_mode(ESP_IEEE802154_AUTO_PENDING_ENABLE); #endif // OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 } otError otPlatRadioAddSrcMatchShortEntry(otInstance *aInstance, uint16_t aShortAddress) { esp_ieee802154_add_pending_addr((uint8_t *)&aShortAddress, true); return OT_ERROR_NONE; } otError otPlatRadioAddSrcMatchExtEntry(otInstance *aInstance, const otExtAddress *aExtAddress) { esp_ieee802154_add_pending_addr(aExtAddress->m8, false); return OT_ERROR_NONE; } otError otPlatRadioClearSrcMatchShortEntry(otInstance *aInstance, uint16_t aShortAddress) { esp_ieee802154_clear_pending_addr((uint8_t *)&aShortAddress, true); return OT_ERROR_NONE; } otError otPlatRadioClearSrcMatchExtEntry(otInstance *aInstance, const otExtAddress *aExtAddress) { esp_ieee802154_clear_pending_addr(aExtAddress->m8, false); return OT_ERROR_NONE; } void otPlatRadioClearSrcMatchShortEntries(otInstance *aInstance) { esp_ieee802154_reset_pending_table(true); } void otPlatRadioClearSrcMatchExtEntries(otInstance *aInstance) { esp_ieee802154_reset_pending_table(false); } otError otPlatRadioEnergyScan(otInstance *aInstance, uint8_t aScanChannel, uint16_t aScanDuration) { esp_ieee802154_energy_detect(aScanDuration); return OT_ERROR_NONE; } otError otPlatRadioGetTransmitPower(otInstance *aInstance, int8_t *aPower) { *aPower = esp_ieee802154_get_txpower(); return OT_ERROR_NONE; } otError otPlatRadioSetTransmitPower(otInstance *aInstance, int8_t aPower) { esp_ieee802154_set_txpower(aPower); return OT_ERROR_NONE; } otError otPlatRadioGetCcaEnergyDetectThreshold(otInstance *aInstance, int8_t *aThreshold) { *aThreshold = esp_ieee802154_get_cca_threshold(); return OT_ERROR_NONE; } otError otPlatRadioSetCcaEnergyDetectThreshold(otInstance *aInstance, int8_t aThreshold) { esp_ieee802154_set_cca_threshold(aThreshold); return OT_ERROR_NONE; } int8_t otPlatRadioGetReceiveSensitivity(otInstance *aInstance) { return ESP_RECEIVE_SENSITIVITY; } void otPlatDiagModeSet(bool mode) { s_diag_mode = mode; } bool otPlatDiagModeGet(void) { return s_diag_mode; } void otPlatDiagTxPowerSet(int8_t tx_power) { OT_UNUSED_VARIABLE(tx_power); } void otPlatDiagChannelSet(uint8_t channel) { OT_UNUSED_VARIABLE(channel); } void otPlatDiagRadioReceived(otInstance *aInstance, otRadioFrame *frame, otError error) { OT_UNUSED_VARIABLE(aInstance); OT_UNUSED_VARIABLE(frame); OT_UNUSED_VARIABLE(error); } void otPlatDiagAlarmCallback(otInstance *aInstance) { OT_UNUSED_VARIABLE(aInstance); } #if OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 void otPlatRadioSetMacKey(otInstance *aInstance, uint8_t aKeyIdMode, uint8_t aKeyId, const otMacKeyMaterial *aPrevKey, const otMacKeyMaterial *aCurrKey, const otMacKeyMaterial *aNextKey, otRadioKeyType aKeyType) { OT_UNUSED_VARIABLE(aInstance); OT_UNUSED_VARIABLE(aKeyIdMode); assert(aKeyType == OT_KEY_TYPE_LITERAL_KEY); assert(aPrevKey != NULL && aCurrKey != NULL && aNextKey != NULL); s_key_id = aKeyId; s_pervious_key = *aPrevKey; s_current_key = *aCurrKey; s_next_key = *aNextKey; } void otPlatRadioSetMacFrameCounter(otInstance *aInstance, uint32_t aMacFrameCounter) { OT_UNUSED_VARIABLE(aInstance); s_mac_frame_counter = aMacFrameCounter; } #endif // OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 uint64_t otPlatRadioGetNow(otInstance *aInstance) { OT_UNUSED_VARIABLE(aInstance); return otPlatTimeGet(); } #if OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE void otPlatRadioUpdateCslSampleTime(otInstance *aInstance, uint32_t aCslSampleTime) { OT_UNUSED_VARIABLE(aInstance); s_csl_sample_time = aCslSampleTime; } static IRAM_ATTR uint16_t get_csl_phase() { uint32_t cur_time = otPlatTimeGet(); uint32_t csl_period_us = s_csl_period * OT_US_PER_TEN_SYMBOLS; uint32_t diff = (csl_period_us - (cur_time % csl_period_us) + (s_csl_sample_time % csl_period_us)) % csl_period_us; return (uint16_t)(diff / OT_US_PER_TEN_SYMBOLS + 1); } #endif // OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE uint16_t otPlatTimeGetXtalAccuracy(void) { return ESP_OPENTHREAD_XTAL_ACCURACY; } #if OPENTHREAD_CONFIG_MLE_LINK_METRICS_SUBJECT_ENABLE otError otPlatRadioConfigureEnhAckProbing(otInstance *aInstance, otLinkMetrics aLinkMetrics, const otShortAddress aShortAddress, const otExtAddress *aExtAddress) { otError error = otLinkMetricsConfigureEnhAckProbing(aShortAddress, aExtAddress, aLinkMetrics); return error; } #endif // OPENTHREAD_CONFIG_MLE_LINK_METRICS_SUBJECT_ENABLE #if OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE otError otPlatRadioEnableCsl(otInstance *aInstance, uint32_t aCslPeriod, otShortAddress aShortAddr, const otExtAddress *aExtAddr) { OT_UNUSED_VARIABLE(aInstance); OT_UNUSED_VARIABLE(aShortAddr); OT_UNUSED_VARIABLE(aExtAddr); s_csl_period = aCslPeriod; return OT_ERROR_NONE; } uint8_t otPlatRadioGetCslAccuracy(otInstance *aInstance) { return ESP_OPENTHREAD_CSL_ACCURACY; } uint8_t otPlatRadioGetCslUncertainty(otInstance *aInstance) { return ESP_OPENTHREAD_CSL_UNCERTAIN; } #endif // events void IRAM_ATTR esp_ieee802154_transmit_done(const uint8_t *frame, const uint8_t *ack, esp_ieee802154_frame_info_t *ack_frame_info) { ETS_ASSERT(frame == (uint8_t *)&s_transmit_psdu); if (ack != NULL) { s_ack_frame.mLength = (uint16_t)(*ack); s_ack_frame.mPsdu = (uint8_t *)(ack + 1); s_ack_frame.mChannel = ack_frame_info->channel; s_ack_frame.mInfo.mRxInfo.mRssi = ack_frame_info->rssi; s_ack_frame.mInfo.mRxInfo.mLqi = ack_frame_info->lqi; s_ack_frame.mInfo.mRxInfo.mTimestamp = ack_frame_info->timestamp; } set_event(EVENT_TX_DONE); } static void IRAM_ATTR convert_to_ot_frame(uint8_t *data, esp_ieee802154_frame_info_t *frame_info, otRadioFrame *radio_frame) { radio_frame->mPsdu = data + 1; radio_frame->mLength = *data; radio_frame->mChannel = frame_info->channel; radio_frame->mInfo.mRxInfo.mRssi = frame_info->rssi; radio_frame->mInfo.mRxInfo.mLqi = frame_info->lqi; radio_frame->mInfo.mRxInfo.mAckedWithFramePending = frame_info->pending; radio_frame->mInfo.mRxInfo.mTimestamp = otPlatTimeGet(); #if OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE radio_frame->mInfo.mRxInfo.mTimestamp = frame_info->timestamp; #endif // OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE } static void IRAM_ATTR enh_ack_set_security_addr_and_key(otRadioFrame *ack_frame) { struct otMacKeyMaterial *key = NULL; uint8_t key_id; ETS_ASSERT(otMacFrameIsSecurityEnabled(ack_frame)); key_id = otMacFrameGetKeyId(ack_frame); ETS_ASSERT(otMacFrameIsKeyIdMode1(ack_frame) && key_id != 0); if (key_id == s_key_id) { key = &s_current_key; } else if (key_id == s_key_id - 1) { key = &s_pervious_key; } else if (key_id == s_key_id + 1) { key = &s_next_key; } else { ETS_ASSERT(false); } s_ack_frame_counter = s_mac_frame_counter; s_ack_key_id = key_id; s_with_security_enh_ack = true; if (otMacFrameIsKeyIdMode1(ack_frame)) { esp_ieee802154_get_extended_address(s_security_addr); memcpy(s_security_key, (*key).mKeyMaterial.mKey.m8, OT_MAC_KEY_SIZE); } esp_ieee802154_set_transmit_security(&ack_frame->mPsdu[-1], s_security_key, s_security_addr); } esp_err_t IRAM_ATTR esp_ieee802154_enh_ack_generator(uint8_t *frame, esp_ieee802154_frame_info_t *frame_info, uint8_t *enhack_frame) { otRadioFrame ack_frame; otRadioFrame ot_frame; uint8_t ack_ie_data[OT_ACK_IE_MAX_SIZE]; uint8_t offset = 0; #if OPENTHREAD_CONFIG_MLE_LINK_METRICS_SUBJECT_ENABLE uint8_t link_metrics_data_len = 0; uint8_t link_metrics_data[OT_ENH_PROBING_IE_DATA_MAX_SIZE]; otMacAddress mac_addr; #endif otError err; ack_frame.mPsdu = enhack_frame + 1; convert_to_ot_frame(frame, frame_info, &ot_frame); #if OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE if (s_csl_period > 0) { offset += otMacFrameGenerateCslIeTemplate(ack_ie_data); } #endif #if OPENTHREAD_CONFIG_MLE_LINK_METRICS_SUBJECT_ENABLE otMacFrameGetSrcAddr(&ot_frame, &mac_addr); link_metrics_data_len = otLinkMetricsEnhAckGenData(&mac_addr, esp_ieee802154_get_recent_lqi(), esp_ieee802154_get_recent_rssi(), link_metrics_data); if (link_metrics_data_len > 0) { offset += otMacFrameGenerateEnhAckProbingIe(ack_ie_data, link_metrics_data, link_metrics_data_len); } #endif err = otMacFrameGenerateEnhAck(&ot_frame, frame_info->pending, ack_ie_data, offset, &ack_frame); if (err != OT_ERROR_NONE) { return ESP_FAIL; } enhack_frame[0] = ack_frame.mLength; s_enhack = enhack_frame; if (otMacFrameIsSecurityEnabled(&ack_frame) && !ack_frame.mInfo.mTxInfo.mIsSecurityProcessed) { otMacFrameSetFrameCounter(&ack_frame, s_mac_frame_counter++); enh_ack_set_security_addr_and_key(&ack_frame); } return ESP_OK; } void IRAM_ATTR esp_ieee802154_receive_done(uint8_t *data, esp_ieee802154_frame_info_t *frame_info) { otRadioFrame ot_frame; ot_frame.mPsdu = data + 1; if (s_recv_queue.used == CONFIG_IEEE802154_RX_BUFFER_SIZE) { ESP_EARLY_LOGE(OT_PLAT_LOG_TAG, "radio receive buffer full!"); return; } convert_to_ot_frame(data, frame_info, &(s_receive_frame[s_recv_queue.tail])); #if OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 // Inform if this frame was acknowledged with secured Enh-ACK. if (otMacFrameIsAckRequested(&ot_frame) && otMacFrameIsVersion2015(&ot_frame)) { s_receive_frame[s_recv_queue.tail].mInfo.mRxInfo.mAckedWithSecEnhAck = s_with_security_enh_ack; s_receive_frame[s_recv_queue.tail].mInfo.mRxInfo.mAckFrameCounter = s_ack_frame_counter; s_receive_frame[s_recv_queue.tail].mInfo.mRxInfo.mAckKeyId = s_ack_key_id; } else { s_receive_frame[s_recv_queue.tail].mInfo.mRxInfo.mAckedWithSecEnhAck = false; } s_with_security_enh_ack = false; #endif // OPENTHREAD_CONFIG_THREAD_VERSION >= OT_THREAD_VERSION_1_2 s_recv_queue.tail = (s_recv_queue.tail + 1) % CONFIG_IEEE802154_RX_BUFFER_SIZE; s_recv_queue.used++; set_event(EVENT_RX_DONE); } void IRAM_ATTR esp_ieee802154_transmit_failed(const uint8_t *frame, esp_ieee802154_tx_error_t error) { ETS_ASSERT(frame == (uint8_t *)&s_transmit_psdu); s_tx_error = error; set_event(EVENT_TX_FAILED); } void IRAM_ATTR esp_ieee802154_receive_sfd_done(void) { } void IRAM_ATTR esp_ieee802154_transmit_sfd_done(uint8_t *frame) { assert(frame == (uint8_t *)&s_transmit_psdu || frame == s_enhack); #if OPENTHREAD_CONFIG_MAC_CSL_RECEIVER_ENABLE otRadioFrame ot_frame; ot_frame.mPsdu = frame + 1; ot_frame.mLength = frame[0]; if (s_csl_period > 0) { otMacFrameSetCslIe(&ot_frame, s_csl_period, get_csl_phase()); } #endif } void IRAM_ATTR esp_ieee802154_energy_detect_done(int8_t power) { s_ed_power = power; set_event(EVENT_ENERGY_DETECT_DONE); } void IRAM_ATTR esp_ieee802154_cca_done(bool channel_free) { } otError otPlatEntropyGet(uint8_t *aOutput, uint16_t aOutputLength) { esp_fill_random(aOutput, aOutputLength); return OT_ERROR_NONE; } otError otPlatRadioSetChannelMaxTransmitPower(otInstance *aInstance, uint8_t aChannel, int8_t aMaxPower) { OT_UNUSED_VARIABLE(aInstance); OT_UNUSED_VARIABLE(aChannel); OT_UNUSED_VARIABLE(aMaxPower); return OT_ERROR_NONE; }