/* * SPDX-FileCopyrightText: 2022-2023 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Unlicense OR CC0-1.0 */ #include #include #include "esp_system.h" #include "esp_log.h" #include "esp_ieee802154.h" #include "esp_console.h" #include "linenoise/linenoise.h" #include "argtable3/argtable3.h" #include "ieee802154_cmd.h" #include "esp_phy_init.h" #include "soc/soc.h" #include "soc/ieee802154_reg.h" static uint8_t s_tx_frame[131] = { 0 }; static const char* TAG = "i154cmd"; static void register_rx(void); static void register_tx(void); static void register_energy(void); static void register_channel(void); static void register_txpower(void); static void register_promisc(void); static void register_panid(void); static void register_shortaddr(void); static void register_extaddr(void); static void register_coordinator(void); static void register_pending(void); static void register_cca(void); static void register_esp154(void); static void register_reg(void); void register_ieee802154_cmd(void) { register_rx(); register_tx(); register_energy(); register_channel(); register_txpower(); register_promisc(); register_panid(); register_shortaddr(); register_extaddr(); register_coordinator(); register_pending(); register_cca(); register_esp154(); register_reg(); } static struct { struct arg_int *duration; struct arg_end *end; } energy_args; static int process_energy(int argc, char **argv) { uint32_t duration = 0; int nerrors = arg_parse(argc, argv, (void **) &energy_args); if (nerrors != 0) { arg_print_errors(stderr, energy_args.end, argv[0]); return 1; } if (energy_args.duration->count) { duration = energy_args.duration->ival[0]; if (energy_args.duration->ival[0]) { ESP_LOGI(TAG, "ed start"); esp_ieee802154_energy_detect(duration); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_energy(void) { energy_args.duration = arg_int0("d", "duration", "", "configure the duration of energy detection"); energy_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "ed", .help = "configure the duration", .hint = NULL, .func = &process_energy, .argtable = &energy_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'channel' command gets/sets the channel number which the radio will work on */ static struct { struct arg_lit *get_channel; struct arg_int *set_channel; struct arg_end *end; } channel_args; static int process_channel(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &channel_args); if (nerrors != 0) { arg_print_errors(stderr, channel_args.end, argv[0]); return 1; } if (channel_args.get_channel->count) { uint8_t channel = esp_ieee802154_get_channel(); ESP_LOGI(TAG, "current channel: %d", channel); } else if (channel_args.set_channel->count) { uint8_t channel = channel_args.set_channel->ival[0]; esp_ieee802154_set_channel(channel); ESP_LOGI(TAG, "set channel: %d", channel); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_channel() { channel_args.get_channel = arg_lit0("g", "get", "get channel number"); channel_args.set_channel = arg_int0("s", "set", "", "set channel number"); channel_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "channel", .help = "get/set the channel number", .hint = NULL, .func = &process_channel, .argtable = &channel_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'txpower' command gets/sets the txpower */ static struct { struct arg_lit *get_txpower; struct arg_int *set_txpower; struct arg_end *end; } txpower_args; static int process_txpower(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &txpower_args); if (nerrors != 0) { arg_print_errors(stderr, txpower_args.end, argv[0]); return 1; } if (txpower_args.get_txpower->count) { int8_t txpower = esp_ieee802154_get_txpower(); ESP_LOGI(TAG, "current txpower: %d", txpower); } else if (txpower_args.set_txpower->count) { int8_t txpower = txpower_args.set_txpower->ival[0]; esp_ieee802154_set_txpower(txpower); ESP_LOGI(TAG, "set txpower: %d", txpower); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_txpower() { txpower_args.get_txpower = arg_lit0("g", "get", "get txpower"); txpower_args.set_txpower = arg_int0("s", "set", "", "set txpower,value range -80dBm~-10dBm"); txpower_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "txpower", .help = "get/set the txpower", .hint = NULL, .func = &process_txpower, .argtable = &txpower_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'promisc' command enable/disable the promiscuous mode */ static struct { struct arg_lit *enable; struct arg_lit *disable; struct arg_lit *get_promisc; struct arg_end *end; } promisc_args; static int process_promisc(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &promisc_args); if (nerrors != 0) { arg_print_errors(stderr, promisc_args.end, argv[0]); return 1; } if (promisc_args.enable->count) { esp_ieee802154_set_promiscuous(true); ESP_LOGI(TAG, "promiscuous mode is enabled"); } else if (promisc_args.disable->count) { esp_ieee802154_set_promiscuous(false); ESP_LOGI(TAG, "promiscuous mode is disabled"); } else if (promisc_args.get_promisc->count) { ESP_LOGI(TAG, "hardware promiscuous mode was %s", esp_ieee802154_get_promiscuous() ? "enabled" : "disabled"); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_promisc() { promisc_args.enable = arg_lit0("e", "enable", "enable the promiscuous mode"); promisc_args.disable = arg_lit0("d", "disable", "disable the promiscuous mode"); promisc_args.get_promisc = arg_lit0("g", "get", "get the promiscuous mode"); promisc_args.end = arg_end(4); const esp_console_cmd_t cmd = { .command = "promisc", .help = "enable/disable/get the promiscuous mode", .hint = NULL, .func = &process_promisc, .argtable = &promisc_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'panid' command set the device Pan ID */ static struct { struct arg_int *set_panid; struct arg_lit *get_panid; struct arg_end *end; } panid_args; static int process_panid(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &panid_args); if (nerrors != 0) { arg_print_errors(stderr, panid_args.end, argv[0]); return 1; } if (panid_args.set_panid->count == 1) { uint16_t panid = panid_args.set_panid->ival[0]; esp_ieee802154_set_panid(panid); ESP_LOGI(TAG, "set panid: 0x%x", panid); } else if (panid_args.get_panid->count) { uint16_t panid = esp_ieee802154_get_panid(); ESP_LOGI(TAG, "current panid: 0x%x", panid); } else { ESP_LOGE(TAG, "no valid arguments"); } return 0; } static void register_panid() { panid_args.set_panid = arg_int0(NULL, NULL, "", "set the device Pan ID"); panid_args.get_panid = arg_lit0("g", "get", "get the device Pan ID"); panid_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "panid", .help = "get/set the device Pan ID", .hint = NULL, .func = &process_panid, .argtable = &panid_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } static struct { struct arg_int *set_shortaddr; struct arg_lit *get_shortaddr; struct arg_end *end; } shortaddr_args; static int process_shortaddr(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &shortaddr_args); if (nerrors != 0) { arg_print_errors(stderr, shortaddr_args.end, argv[0]); return 1; } if (shortaddr_args.set_shortaddr->count == 1) { uint16_t short_address = shortaddr_args.set_shortaddr->ival[0]; esp_ieee802154_set_short_address(short_address); ESP_LOGI(TAG, "set shortaddr: 0x%x", short_address); } else if (shortaddr_args.get_shortaddr->count) { uint16_t short_address = esp_ieee802154_get_short_address(); ESP_LOGI(TAG, "current shortaddr: 0x%x", short_address); } else { ESP_LOGE(TAG, "no valid arguments"); } return 0; } static void register_shortaddr() { shortaddr_args.set_shortaddr = arg_int0(NULL, NULL, "", "set the device short address"); shortaddr_args.get_shortaddr = arg_lit0("g", "get", "get the device short address"); shortaddr_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "shortaddr", .help = "get/set the device short address", .hint = NULL, .func = &process_shortaddr, .argtable = &shortaddr_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } static struct { struct arg_lit *get_extaddr; struct arg_int *set_extaddr; struct arg_end *end; } extaddr_args; static int process_extaddr(int argc, char **argv) { uint8_t extaddr[8] = {0}; int nerrors = arg_parse(argc, argv, (void **) &extaddr_args); if (nerrors != 0) { arg_print_errors(stderr, extaddr_args.end, argv[0]); return 1; } if (extaddr_args.set_extaddr->count == 8) { for (uint8_t i = 0; i < 8; i++) { extaddr[i] = extaddr_args.set_extaddr->ival[i]; } esp_ieee802154_set_extended_address(extaddr); ESP_LOGI(TAG, "set extaddr: %02x%02x%02x%02x%02x%02x%02x%02x", extaddr[7], extaddr[6], extaddr[5], extaddr[4], extaddr[3], extaddr[2], extaddr[1], extaddr[0]); } else if (extaddr_args.get_extaddr->count) { esp_ieee802154_get_extended_address(extaddr); ESP_LOGI(TAG, "get extaddr: %02x%02x%02x%02x%02x%02x%02x%02x", extaddr[7], extaddr[6], extaddr[5], extaddr[4], extaddr[3], extaddr[2], extaddr[1], extaddr[0]); } else { ESP_LOGE(TAG, "no valid arguments"); } return 0; } static void register_extaddr() { extaddr_args.set_extaddr = arg_intn(NULL, NULL, "", 0, 127, "set the device extended address"); extaddr_args.get_extaddr = arg_lit0("g", "get", "get the device extended address"); extaddr_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "extaddr", .help = "set/get the device extended address", .hint = NULL, .func = &process_extaddr, .argtable = &extaddr_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'coordinator' command enable/disable the coordinator */ static struct { struct arg_lit *enable; struct arg_lit *disable; struct arg_lit *get_coordinator; struct arg_end *end; } coordinator_args; static int process_coordinator(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &coordinator_args); if (nerrors != 0) { arg_print_errors(stderr, coordinator_args.end, argv[0]); return 1; } if (coordinator_args.enable->count) { esp_ieee802154_set_coordinator(true); ESP_LOGI(TAG, "hardware coordinator is enabled"); } else if (coordinator_args.disable->count) { esp_ieee802154_set_coordinator(false); ESP_LOGI(TAG, "hardware coordinator is disabled"); } else if (coordinator_args.get_coordinator->count) { ESP_LOGI(TAG, "hardware coordinator was %s", esp_ieee802154_get_coordinator() ? "enabled" : "disabled"); } return 0; } static void register_coordinator() { coordinator_args.enable = arg_lit0("e", "enable", "enable the coordinator"); coordinator_args.disable = arg_lit0("d", "disable", "disable the coordinator"); coordinator_args.get_coordinator = arg_lit0("g", "get", "get the coordinator"); coordinator_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "coordinator", .help = "enable/disable/get the coordinator", .hint = NULL, .func = &process_coordinator, .argtable = &coordinator_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } static struct { struct arg_int *set_mode; struct arg_lit *get_mode; struct arg_lit *reset; struct arg_int *add_addr; struct arg_int *del_addr; struct arg_end *end; } pending_args; static int process_pending(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &pending_args); if (nerrors != 0) { arg_print_errors(stderr, pending_args.end, argv[0]); return 1; } esp_ieee802154_pending_mode_t pending_mode = 0; if (pending_args.set_mode->count) { pending_mode = pending_args.set_mode->ival[0]; esp_ieee802154_set_pending_mode(pending_mode); ESP_LOGI(TAG, "set auto pending mode as: %d", pending_mode); } else if (pending_args.get_mode->count) { pending_mode = esp_ieee802154_get_pending_mode(); ESP_LOGI(TAG, "get auto pending mode as: %d", pending_mode); } else if (pending_args.reset->count) { esp_ieee802154_reset_pending_table(false); esp_ieee802154_reset_pending_table(true); ESP_LOGI(TAG, "clear the pending address table"); } else if (pending_args.add_addr->count == 2) { uint8_t short_addr[2]; short_addr[0] = pending_args.add_addr->ival[0]; short_addr[1] = pending_args.add_addr->ival[1]; esp_ieee802154_add_pending_addr(short_addr, true); ESP_LOGI(TAG, "add pending shortaddr: 0x%02x%02x", short_addr[1], short_addr[0]); } else if (pending_args.add_addr->count == 8) { uint8_t extaddr[8] = {0}; for (uint8_t i = 0; i < 8; i++) { extaddr[i] = pending_args.add_addr->ival[i]; } esp_ieee802154_add_pending_addr(extaddr, false); ESP_LOGI(TAG, "add pending extaddr: 0x%02x%02x%02x%02x%02x%02x%02x%02x", extaddr[7], extaddr[6], extaddr[5], extaddr[4], extaddr[3], extaddr[2], extaddr[1], extaddr[0]); } else if (pending_args.del_addr->count == 2) { uint8_t short_addr[2]; short_addr[0] = pending_args.del_addr->ival[0]; short_addr[1] = pending_args.del_addr->ival[1]; esp_ieee802154_clear_pending_addr(short_addr, true); ESP_LOGI(TAG, "delete pending shortaddr: 0x%02x%02x", short_addr[1], short_addr[0]); } else if (pending_args.del_addr->count == 8) { uint8_t extaddr[8] = {0}; for (uint8_t i = 0; i < 8; i++) { extaddr[i] = pending_args.del_addr->ival[i]; } esp_ieee802154_clear_pending_addr(extaddr, false); ESP_LOGI(TAG, "delete pending extaddr: 0x%02x%02x%02x%02x%02x%02x%02x%02x", extaddr[7], extaddr[6], extaddr[5], extaddr[4], extaddr[3], extaddr[2], extaddr[1], extaddr[0]); } else { ESP_LOGE(TAG, "no valid arguments"); } return 0; } static void register_pending() { pending_args.set_mode = arg_int0("m", "mode", "", "set the autopending mode (0: disable; 1: enable; 2: enhanced)"); pending_args.get_mode = arg_lit0("g", "get", "get the autopending mode (0: disable; 1: enable; 2: enhanced)"); pending_args.reset = arg_lit0("r", "reset", "reset the pending address table"); pending_args.add_addr = arg_intn(NULL, NULL, "", 0, 8, "add the address to pending table (2 bytes for short address, 8 bytes for extended address)"); pending_args.del_addr = arg_intn("d", "delete", "", 0, 8, "delete the address from pending table (2 bytes for short address, 8 bytes for extended address)"); pending_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "pending", .help = "configure the pending address table", .hint = NULL, .func = &process_pending, .argtable = &pending_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } //CCA command static struct { struct arg_int *cca_threshold_set; struct arg_int *cca_mode_set; struct arg_lit *cca_cfg_get; struct arg_end *end; } cca_args; static int process_cca(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &cca_args); if (nerrors != 0) { arg_print_errors(stderr, cca_args.end, argv[0]); return 1; } int8_t cca_threshold = 0; esp_ieee802154_cca_mode_t cca_mode = 0; if (cca_args.cca_threshold_set->count) { cca_threshold = cca_args.cca_threshold_set->ival[0]; esp_ieee802154_set_cca_threshold(cca_threshold); ESP_LOGI(TAG, "set cca threshold as: %d", cca_threshold); } else if (cca_args.cca_mode_set->count) { cca_mode = cca_args.cca_mode_set->ival[0]; esp_ieee802154_set_cca_mode(cca_mode); ESP_LOGI(TAG, "set cca mode as: %d", cca_mode); } else if (cca_args.cca_cfg_get->count) { ESP_LOGI(TAG, "threshold:%d dB, mode: %d", esp_ieee802154_get_cca_threshold(), esp_ieee802154_get_cca_mode()); } else { ESP_LOGI(TAG, "no valid arguments"); } return 0; } static void register_cca() { cca_args.cca_threshold_set = arg_int0("v", "value", "", "cca threshold setting"); cca_args.cca_mode_set = arg_int0("m", "mode", "", "cca mode, 0: carrier; 1: ED; 2: carrier or ED; 3: carrier and ED"); cca_args.cca_cfg_get = arg_lit0("g", "get", "get the cca cfg"); cca_args.end = arg_end(4); const esp_console_cmd_t cmd = { .command = "cca", .help = "cca config", .hint = NULL, .func = &process_cca, .argtable = &cca_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'esp_154' command enable/disable initialize the IEEE 802.15.4 subsystem */ static struct { struct arg_lit *enable; struct arg_lit *disable; struct arg_end *end; } esp154_args; static int process_esp154(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &esp154_args); if (nerrors != 0) { arg_print_errors(stderr, esp154_args.end, argv[0]); return 1; } if (esp154_args.enable->count) { esp_ieee802154_enable(); ESP_LOGI(TAG, "initialize the IEEE 802.15.4 subsystem"); } else if (esp154_args.disable->count) { esp_ieee802154_disable(); ESP_LOGI(TAG, "deinitialize the IEEE 802.15.4 subsystem"); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_esp154() { esp154_args.enable = arg_lit0("e", "enable", "initialize the IEEE 802.15.4 subsystem"); esp154_args.disable = arg_lit0("d", "disable", "deinitialize the IEEE 802.15.4 subsystem"); esp154_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "esp154", .help = "enable/disable initialize the IEEE 802.15.4 subsystem", .hint = NULL, .func = &process_esp154, .argtable = &esp154_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } /* 'reg' command reads/writes the registers */ static struct { struct arg_int *get_reg; struct arg_int *set_reg; struct arg_int *value; struct arg_end *end; } reg_args; static int process_reg(int argc, char **argv) { uint32_t base = IEEE802154_REG_BASE; int nerrors = arg_parse(argc, argv, (void **) ®_args); if (nerrors != 0) { arg_print_errors(stderr, reg_args.end, argv[0]); return 1; } if (reg_args.get_reg->count == 1) { uint32_t reg_offset = reg_args.get_reg->ival[0]; uint32_t reg_value = REG_READ(reg_offset + base); ESP_LOGI(TAG, "reg 0x%lx value: 0x%lx", reg_offset, reg_value); } else if (reg_args.set_reg->count == 1 && reg_args.value->count == 1) { uint32_t reg_offset = reg_args.set_reg->ival[0]; uint32_t reg_value = reg_args.value->ival[0]; REG_WRITE(reg_offset + base, reg_value); ESP_LOGI(TAG, "write reg 0x%lx: 0x%lx", reg_offset, reg_value); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_reg() { reg_args.get_reg = arg_int0("r", "read", "
", "read the register value"); reg_args.set_reg = arg_int0("w", "write", "
", "register address to be written"); reg_args.value = arg_int0("v", "value", "", "register value to be written"); reg_args.end = arg_end(6); const esp_console_cmd_t cmd = { .command = "reg", .help = "read/write the register", .hint = NULL, .func = &process_reg, .argtable = ®_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } static struct { struct arg_int *length; struct arg_lit *cca_enable; struct arg_int *frame; struct arg_int *offset; struct arg_end *end; } tx_args; static int process_tx(int argc, char **argv) { uint8_t tx_frame[128] = { 0 }; uint8_t offset = 0; bool cca = false; int nerrors = arg_parse(argc, argv, (void **) &tx_args); if (nerrors != 0) { arg_print_errors(stderr, tx_args.end, argv[0]); return 1; } memset(tx_frame, 0, sizeof(tx_frame)); if (tx_args.offset->count && (tx_args.offset->ival[0] >= 0 && tx_args.offset->ival[0] <= 3)) { offset = tx_args.offset->ival[0]; } if (tx_args.length->count) { tx_frame[0] = tx_args.length->ival[0]; for (uint8_t i = 0; i < tx_frame[0]; i++) { tx_frame[i + 1] = i; } } else if (tx_args.frame->count) { tx_frame[0] = tx_args.frame->count; for (uint8_t i = 0; i < tx_frame[0]; i++) { tx_frame[i + 1] = tx_args.frame->ival[i]; } } if (tx_args.cca_enable->count) { cca = true; } memcpy(s_tx_frame + offset, tx_frame, sizeof(tx_frame)); esp_ieee802154_transmit(s_tx_frame, cca); return 0; } static void register_tx(void) { tx_args.length = arg_int0("l", "length", "", "frame length"); tx_args.cca_enable = arg_lit0("C", "cca_enable", "set cca trigging tx mode true"); tx_args.frame = arg_intn(NULL, NULL, "", 0, 127, "transmit raw frame"); tx_args.offset = arg_int0("o", "offset", "", "tx buffer offset"); tx_args.end = arg_end(5); const esp_console_cmd_t cmd = { .command = "tx", .help = "transmit IEEE 802154 MAC frame", .hint = NULL, .func = &process_tx, .argtable = &tx_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } static struct { struct arg_int *receive; struct arg_end *end; } rx_args; static int process_rx(int argc, char **argv) { int nerrors = arg_parse(argc, argv, (void **) &rx_args); if (nerrors != 0) { arg_print_errors(stderr, rx_args.end, argv[0]); return 1; } if (rx_args.receive->count == 1) { if (rx_args.receive->ival[0] == 0) { esp_ieee802154_sleep(); ESP_LOGI(TAG, "radio exit receive mode"); } else if (rx_args.receive->ival[0] == 1) { // receive, non-blocking ESP_LOGI(TAG, "RX Start"); esp_ieee802154_receive(); esp_ieee802154_set_rx_when_idle(true); } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } } else { ESP_LOGE(TAG, "no valid arguments"); return 1; } return 0; } static void register_rx(void) { rx_args.receive = arg_int0("r", "receive", "", "configure the radio receive mode, 0: disable; 1: enable"); rx_args.end = arg_end(2); const esp_console_cmd_t cmd = { .command = "rx", .help = "enable/disable the receive mode", .hint = NULL, .func = &process_rx, .argtable = &rx_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&cmd)); } static void esp_ieee802154_frame_print(const uint8_t *frame) { for (uint8_t idx = 1; idx < frame[0]; idx += 8) { ESP_EARLY_LOGI(TAG, "%02x %02x %02x %02x %02x %02x %02x %02x", frame[idx], frame[idx + 1], frame[idx + 2], frame[idx + 3], frame[idx + 4], frame[idx + 5], frame[idx + 6], frame[idx + 7]); } } void esp_ieee802154_transmit_done(const uint8_t *frame, const uint8_t *ack, esp_ieee802154_frame_info_t *ack_frame_info) { ESP_EARLY_LOGI(TAG, "Tx Done %d bytes", frame[0]); esp_ieee802154_frame_print(frame); if (ack != NULL) { ESP_EARLY_LOGI(TAG, "Rx ack %d bytes", ack[0]); esp_ieee802154_frame_print(ack); } } void esp_ieee802154_receive_done(uint8_t *frame, esp_ieee802154_frame_info_t *frame_info) { ESP_EARLY_LOGI(TAG, "Rx Done %d bytes", frame[0]); esp_ieee802154_frame_print(frame); } void esp_ieee802154_energy_detect_done(int8_t power) { ESP_EARLY_LOGI(TAG, "ed_scan_rss_value: %d dB", power); } void esp_ieee802154_transmit_sfd_done(uint8_t *frame) { ESP_EARLY_LOGI(TAG, "tx sfd done, Radio state: %d", esp_ieee802154_get_state()); } void esp_ieee802154_receive_sfd_done(void) { ESP_EARLY_LOGI(TAG, "rx sfd done, Radio state: %d", esp_ieee802154_get_state()); } void esp_ieee802154_transmit_failed(const uint8_t *frame, esp_ieee802154_tx_error_t error) { ESP_EARLY_LOGI(TAG, "the Frame Transmission failed, Failure reason: %d", error); }