#include "pxt.h" using namespace pxt; #define MAX_FIELD_NAME_LENGTH 12 #define MAX_PAYLOAD_LENGTH 20 #define PACKET_PREFIX_LENGTH 9 #define VALUE_PACKET_NAME_LEN_OFFSET 13 // Packet Spec: // | 0 | 1 ... 4 | 5 ... 8 | 9 ... 28 // ---------------------------------------------------------------- // | packet type | system time | serial number | payload // // Serial number defaults to 0 unless enabled by user // payload: number (9 ... 12) #define PACKET_TYPE_NUMBER 0 // payload: number (9 ... 12), name length (13), name (14 ... 26) #define PACKET_TYPE_VALUE 1 // payload: string length (9), string (10 ... 28) #define PACKET_TYPE_STRING 2 //% color=270 weight=34 namespace radio { // ------------------------------------------------------------------------- // Radio // ------------------------------------------------------------------------- bool radioEnabled = false; bool transmitSerialNumber = false; PacketBuffer packet; uint8_t type; uint32_t time; uint32_t serial; int value; StringData* msg; int radioEnable() { int r = uBit.radio.enable(); if (r != MICROBIT_OK) { uBit.panic(43); return r; } if (!radioEnabled) { uBit.radio.setGroup(pxt::programHash()); radioEnabled = true; } return r; } void broadcastMessage(int message) { if (radioEnable() != MICROBIT_OK) return; uBit.radio.event.eventReceived(MicroBitEvent(MES_BROADCAST_GENERAL_ID, message, CREATE_ONLY)); } void onBroadcastMessageReceived(int message, Action f) { if (radioEnable() != MICROBIT_OK) return; registerWithDal(MES_BROADCAST_GENERAL_ID, message, f); } void setPacketPrefix(uint8_t* buf, int type) { // prefix: type (0), time (1..4), serial (5..8) uint32_t t = system_timer_current_time(); uint32_t sn = transmitSerialNumber ? microbit_serial_number() : 0; buf[0] = (uint8_t) type; memcpy(buf + 1, &t, 4); memcpy(buf + 5, &sn, 4); } uint8_t copyStringValue(uint8_t* buf, StringData* data, uint8_t maxLength) { ManagedString s(data); uint8_t len = min(maxLength, s.length()); // One byte for length of the string buf[0] = len; if (len > 0) { memcpy(buf + 1, s.toCharArray(), len); } return len + 1; } StringData* getStringValue(uint8_t* buf, uint8_t maxLength) { // First byte is the string length uint8_t len = min(maxLength, buf[0]); if (len) { char name[maxLength + 1]; memcpy(name, buf + 1, len); name[len] = 0; return ManagedString(name).leakData(); } return ManagedString().leakData(); } void writePacketAsJSON(uint8_t tp, int v, int s, int t, StringData* m) { // Convert the packet to JSON and send over serial uBit.serial.send("{"); uBit.serial.send("\"t\":"); uBit.serial.send(t); uBit.serial.send(",\"s\":"); uBit.serial.send(s); if (tp == PACKET_TYPE_STRING || tp == PACKET_TYPE_VALUE) { uBit.serial.send(",\"n\":\""); uBit.serial.send(m); uBit.serial.send("\""); } if (tp == PACKET_TYPE_NUMBER || tp == PACKET_TYPE_VALUE) { uBit.serial.send(",\"v\":"); uBit.serial.send(v); } uBit.serial.send("}\r\n"); } /** * Takes a packet from the micro:bit radio queue. * @param writeToSerial if true, write the received packet to serial without updating the global packet; if false, update the global packet instead */ void receivePacket(bool writeToSerial) { PacketBuffer p = uBit.radio.datagram.recv(); uint8_t* buf = p.getBytes(); uint8_t tp; int t; int s; int v; StringData* m; memcpy(&tp, buf, 1); memcpy(&t, buf + 1, 4); memcpy(&s, buf + 5, 4); if (tp == PACKET_TYPE_STRING) { v = 0; m = getStringValue(buf + PACKET_PREFIX_LENGTH, MAX_PAYLOAD_LENGTH - 1); } else { memcpy(&v, buf + 9, 4); if (tp == PACKET_TYPE_VALUE) { m = getStringValue(buf + VALUE_PACKET_NAME_LEN_OFFSET, MAX_FIELD_NAME_LENGTH); } else { m = ManagedString().leakData(); } } if (!writeToSerial) { // Refresh global packet packet = p; type = tp; time = t; serial = s; value = v; msg = m; } else { writePacketAsJSON(tp, v, s, t, m); } } /** * Broadcasts a number over radio to any connected micro:bit in the group. */ //% help=radio/send-number //% weight=60 //% blockId=radio_datagram_send block="radio send number %value" blockGap=8 void sendNumber(int value) { if (radioEnable() != MICROBIT_OK) return; uint8_t length = PACKET_PREFIX_LENGTH + sizeof(uint32_t); uint8_t buf[length]; memset(buf, 0, length); setPacketPrefix(buf, PACKET_TYPE_NUMBER); memcpy(buf + PACKET_PREFIX_LENGTH, &value, 4); uBit.radio.datagram.send(buf, length); } /** * Broadcasts a name / value pair along with the device serial number * and running time to any connected micro:bit in the group. * @param name the field name (max 12 characters), eg: "name" * @param value the numberic value */ //% help=radio/send-value //% weight=59 //% blockId=radio_datagram_send_value block="radio send|value %name|= %value" blockGap=8 void sendValue(StringData* name, int value) { if (radioEnable() != MICROBIT_OK) return; ManagedString n(name); uint8_t buf[32]; memset(buf, 0, 32); setPacketPrefix(buf, PACKET_TYPE_VALUE); memcpy(buf + PACKET_PREFIX_LENGTH, &value, 4); int stringLen = copyStringValue(buf + VALUE_PACKET_NAME_LEN_OFFSET, name, MAX_FIELD_NAME_LENGTH); uBit.radio.datagram.send(buf, VALUE_PACKET_NAME_LEN_OFFSET + stringLen); } /** * Broadcasts a string along with the device serial number * and running time to any connected micro:bit in the group. */ //% help=radio/send-string //% weight=58 //% blockId=radio_datagram_send_string block="radio send string %msg" void sendString(StringData* msg) { if (radioEnable() != MICROBIT_OK) return; uint8_t buf[32]; memset(buf, 0, 32); setPacketPrefix(buf, PACKET_TYPE_STRING); int stringLen = copyStringValue(buf + PACKET_PREFIX_LENGTH, msg, MAX_PAYLOAD_LENGTH - 1); uBit.radio.datagram.send(buf, PACKET_PREFIX_LENGTH + stringLen); } /** * Reads the next packet from the radio queue and and writes it to serial * as JSON. */ //% help=radio/write-value-to-serial //% weight=3 //% blockId=radio_write_value_serial block="radio write value to serial" //% deprecated=true void writeValueToSerial() { if (radioEnable() != MICROBIT_OK) return; receivePacket(true); } /** * Writes the last received packet to serial as JSON. This should be called * within an ``onDataPacketReceived`` callback. */ //% help=radio/write-received-packet-to-serial //% weight=3 //% blockId=radio_write_packet_serial block="radio write received packet to serial" //% advanced=true void writeReceivedPacketToSerial() { if (radioEnable() != MICROBIT_OK) return; writePacketAsJSON(type, value, (int) serial, (int) time, msg); } /** * Reads the next packet from the radio queue and returns the packet's number * payload or 0 if the packet did not contain a number. */ //% help=radio/receive-number //% weight=46 //% blockId=radio_datagram_receive block="radio receive number" blockGap=8 //% deprecated=true int receiveNumber() { if (radioEnable() != MICROBIT_OK) return 0; receivePacket(false); return value; } /** * Registers code to run when a packet is received over radio. */ //% help=radio/on-data-received //% weight=50 //% blockId=radio_datagram_received_event block="radio on data received" blockGap=8 //% deprecated=true void onDataReceived(Action body) { if (radioEnable() != MICROBIT_OK) return; registerWithDal(MICROBIT_ID_RADIO, MICROBIT_RADIO_EVT_DATAGRAM, body); // make sure the receive buffer has a free spot receiveNumber(); } /** * Reads the next packet from the radio queue and returns the packet's string * payload or the empty string if the packet did not contain a string. */ //% blockId=radio_datagram_receive_string block="radio receive string" blockGap=8 //% weight=44 //% help=radio/receive-string //% deprecated=true StringData* receiveString() { if (radioEnable() != MICROBIT_OK) return ManagedString().leakData(); receivePacket(false); return msg; } /** * Gets the received signal strength indicator (RSSI) from the last packet taken * from the radio queue (via ``receiveNumber``, ``receiveString``, etc). Not supported in simulator. * namespace=radio */ //% help=radio/received-signal-strength //% weight=40 //% blockId=radio_datagram_rssi block="radio received signal strength" //% deprecated=true int receivedSignalStrength() { if (radioEnable() != MICROBIT_OK) return 0; return packet.getRSSI(); } /** * Sets the group id for radio communications. A micro:bit can only listen to one group ID at any time. * @ param id the group id between ``0`` and ``255``, 1 eg */ //% help=radio/set-group //% weight=10 blockGap=8 advanced=true //% blockId=radio_set_group block="radio set group %ID" void setGroup(int id) { if (radioEnable() != MICROBIT_OK) return; uBit.radio.setGroup(id); } /** * Change the output power level of the transmitter to the given value. * @param power a value in the range 0..7, where 0 is the lowest power and 7 is the highest. eg: 7 */ //% help=radio/set-transmit-power //% weight=9 blockGap=8 //% blockId=radio_set_transmit_power block="radio set transmit power %power" //% advanced=true void setTransmitPower(int power) { if (radioEnable() != MICROBIT_OK) return; uBit.radio.setTransmitPower(power); } /** * Set the radio to transmit the serial number in each message. * @param transmit value indicating if the serial number is transmitted, eg: true */ //% help=radio/set-transmit-serial-number //% weight=8 blockGap=8 //% blockId=radio_set_transmit_serial_number block="radio set transmit serial number %transmit" //% advanced=true void setTransmitSerialNumber(bool transmit) { if (radioEnable() != MICROBIT_OK) return; transmitSerialNumber = transmit; } /** * Returns the number payload from the last packet taken from the radio queue * (via ``receiveNumber``, ``receiveString``, etc) or 0 if that packet did not * contain a number. */ //% help=radio/received-number int receivedNumber() { if (radioEnable() != MICROBIT_OK) return 0; return value; } /** * Returns the serial number of the sender micro:bit from the last packet taken * from the radio queue (via ``receiveNumber``, ``receiveString``, etc) or 0 if * that packet did not send a serial number. */ //% help=radio/received-serial uint32_t receivedSerial() { if (radioEnable() != MICROBIT_OK) return 0; return serial; } /** * Returns the string payload from the last packet taken from the radio queue * (via ``receiveNumber``, ``receiveString``, etc) or the empty string if that * packet did not contain a string. */ //% help=radio/received-string StringData* receivedString() { if (radioEnable() != MICROBIT_OK) return ManagedString().leakData(); return msg; } /** * Returns the system time of the sender micro:bit at the moment when it sent the * last packet taken from the radio queue (via ``receiveNumber``, * ``receiveString``, etc). */ //% help=radio/received-time uint32_t receivedTime() { if (radioEnable() != MICROBIT_OK) return 0; return time; } }