#include #include #include "device.h" #include "hardware/Serial.h" #include "hardware/LED.h" #include "util/FIFO16.h" #include "util/time.h" #include "KISS.h" uint8_t packet_queue[CONFIG_QUEUE_SIZE]; uint8_t tx_buffer[AX25_MAX_FRAME_LEN]; volatile uint8_t queue_height = 0; volatile size_t queued_bytes = 0; volatile size_t queue_cursor = 0; volatile size_t current_packet_start = 0; FIFOBuffer16 packet_starts; size_t packet_starts_buf[CONFIG_QUEUE_MAX_LENGTH+1]; FIFOBuffer16 packet_lengths; size_t packet_lengths_buf[CONFIG_QUEUE_MAX_LENGTH+1]; AX25Ctx *ax25ctx; Afsk *channel; Serial *serial; volatile uint32_t last_serial_read = 0; size_t frame_len; bool IN_FRAME; bool ESCAPE; uint8_t command = CMD_UNKNOWN; unsigned long custom_preamble = CONFIG_AFSK_PREAMBLE_LEN; unsigned long custom_tail = CONFIG_AFSK_TRAILER_LEN; unsigned long slotTime = 200; uint8_t p = CONFIG_CSMA_P; void kiss_init(AX25Ctx *ax25, Afsk *afsk, Serial *ser) { ax25ctx = ax25; serial = ser; channel = afsk; memset(packet_queue, 0, sizeof(packet_queue)); memset(packet_starts_buf, 0, sizeof(packet_starts)); memset(packet_lengths_buf, 0, sizeof(packet_lengths)); fifo16_init(&packet_starts, packet_starts_buf, sizeof(packet_starts_buf)); fifo16_init(&packet_lengths, packet_lengths_buf, sizeof(packet_lengths_buf)); } void kiss_poll(void) { while (!fifo_isempty_locked(&serialFIFO)) { char sbyte = fifo_pop_locked(&serialFIFO); kiss_serialCallback(sbyte); last_serial_read = timer_clock(); } } // TODO: Remove debug functions //size_t decodes = 0; void kiss_messageCallback(AX25Ctx *ctx) { //decodes++; //printf("%d\r\n", decodes); fputc(FEND, &serial->uart0); fputc(0x00, &serial->uart0); for (unsigned i = 0; i < ctx->frame_len-2; i++) { uint8_t b = ctx->buf[i]; if (b == FEND) { fputc(FESC, &serial->uart0); fputc(TFEND, &serial->uart0); } else if (b == FESC) { fputc(FESC, &serial->uart0); fputc(TFESC, &serial->uart0); } else { fputc(b, &serial->uart0); } } fputc(FEND, &serial->uart0); } void kiss_csma(void) { if (queue_height > 0) { #if BITRATE == 2400 if (!channel->hdlc.dcd) { ticks_t timeout = last_serial_read + ms_to_ticks(CONFIG_SERIAL_TIMEOUT_MS); if (timer_clock() > timeout) { if (p == 255) { kiss_flushQueue(); } else { // TODO: Implement real CSMA } } } #else if (!channel->hdlc.dcd) { if (p == 255) { kiss_flushQueue(); } else { // TODO: Implement real CSMA } } #endif } } // TODO: Remove this void kiss_flushQueueDebug(void) { printf("Queue height %d\r\n", queue_height); for (size_t n = 0; n < queue_height; n++) { size_t start = fifo16_pop(&packet_starts); size_t length = fifo16_pop(&packet_lengths); printf("--- Packet %d, %d bytes ---\r\n", n+1, length); for (size_t i = 0; i < length; i++) { size_t pos = (start+i)%CONFIG_QUEUE_SIZE; printf("%02x", packet_queue[pos]); } printf("\r\n\r\n"); } queue_height = 0; queued_bytes = 0; } volatile bool queue_flushing = false; void kiss_flushQueue(void) { if (!queue_flushing) { queue_flushing = true; size_t processed = 0; for (size_t n = 0; n < queue_height; n++) { size_t start = fifo16_pop_locked(&packet_starts); size_t length = fifo16_pop_locked(&packet_lengths); //kiss_poll(); for (size_t i = 0; i < length; i++) { size_t pos = (start+i)%CONFIG_QUEUE_SIZE; tx_buffer[i] = packet_queue[pos]; } ax25_sendRaw(ax25ctx, tx_buffer, length); processed++; } if (processed < queue_height) { while (true) { LED_TX_ON(); LED_RX_ON(); } } //printf("Processed %d\r\n", processed); queue_height = 0; queued_bytes = 0; queue_flushing = false; } } uint8_t kiss_queuedPackets(void) { return 0; } bool kiss_queueIsFull(void) { return false; } void kiss_serialCallback(uint8_t sbyte) { if (IN_FRAME && sbyte == FEND && command == CMD_DATA) { IN_FRAME = false; if (queue_height < CONFIG_QUEUE_MAX_LENGTH && queued_bytes < CONFIG_QUEUE_SIZE) { queue_height++; size_t s = current_packet_start; size_t e = queue_cursor-1; if (e == -1) e = CONFIG_QUEUE_SIZE-1; size_t l = (s < e) ? e - s + 1 : CONFIG_QUEUE_SIZE - s + e + 1; fifo16_push_locked(&packet_starts, s); fifo16_push_locked(&packet_lengths, l); current_packet_start = queue_cursor; //printf("Queue height %d\r\n", queue_height); } } else if (sbyte == FEND) { IN_FRAME = true; command = CMD_UNKNOWN; frame_len = 0; } else if (IN_FRAME && frame_len < AX25_MAX_FRAME_LEN) { // Have a look at the command byte first if (frame_len == 0 && command == CMD_UNKNOWN) { // OpenModem supports only one HDLC port, so we // strip off the port nibble of the command byte sbyte = sbyte & 0x0F; command = sbyte; if (command == CMD_DATA) current_packet_start = queue_cursor; } else if (command == CMD_DATA) { if (sbyte == FESC) { ESCAPE = true; } else { if (ESCAPE) { if (sbyte == TFEND) sbyte = FEND; if (sbyte == TFESC) sbyte = FESC; ESCAPE = false; } if (queue_height < CONFIG_QUEUE_MAX_LENGTH && queued_bytes < CONFIG_QUEUE_SIZE) { queued_bytes++; packet_queue[queue_cursor++] = sbyte; if (queue_cursor == CONFIG_QUEUE_SIZE) queue_cursor = 0; } } } else if (command == CMD_TXDELAY) { custom_preamble = sbyte * 10UL; } else if (command == CMD_TXTAIL) { custom_tail = sbyte * 10; } else if (command == CMD_SLOTTIME) { slotTime = sbyte * 10; } else if (command == CMD_P) { p = sbyte; } else if (command == CMD_FLUSHQUEUE) { kiss_flushQueue(); // TODO: Remove this } else if (command == CMD_FLUSHQUEUE_DEBUG) { kiss_flushQueueDebug(); } else if (command == CMD_LED_INTENSITY) { if (sbyte == FESC) { ESCAPE = true; } else { if (ESCAPE) { if (sbyte == TFEND) sbyte = FEND; if (sbyte == TFESC) sbyte = FESC; ESCAPE = false; } LED_setIntensity(sbyte); } } } }