tnc3-firmware/TNC/HDLCEncoder.hpp

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// Copyright 2015 Mobilinkd LLC <rob@mobilinkd.com>
// All rights reserved.
#ifndef INC_HDLCENCODER_HPP_
#define INC_HDLCENCODER_HPP_
#include "AFSKModulator.hpp"
#include "HdlcFrame.hpp"
#include "NRZI.hpp"
#include "PTT.hpp"
#include "GPIO.hpp"
#include "KissHardware.hpp"
#include "AudioInput.hpp"
#include "DCD.h"
#include "main.h"
#include <cmsis_os.h>
#include <cstdint>
namespace mobilinkd { namespace tnc { namespace hdlc {
using namespace mobilinkd::libafsk;
struct Encoder {
static const uint8_t FLAG = 0x7E;
enum class state_type {
STATE_IDLE,
STATE_HEAD,
STATE_FRAME,
STATE_CRC_LOW,
STATE_CRC_HIGH,
STATE_TAIL,
};
uint8_t tx_delay_;
uint8_t tx_tail_;
uint8_t p_persist_;
uint8_t slot_time_;
bool duplex_;
state_type state_;
int ones_;
NRZI nrzi_;
uint16_t crc_;
osMessageQId input_;
AFSKModulator* modulator_;
volatile bool running_;
bool send_delay_; // Avoid sending the preamble for back-to-back frames.
Encoder(osMessageQId input, AFSKModulator* output)
: tx_delay_(kiss::settings().txdelay), tx_tail_(kiss::settings().txtail)
, p_persist_(kiss::settings().ppersist), slot_time_(kiss::settings().slot)
, duplex_(kiss::settings().duplex), state_(state_type::STATE_IDLE)
, ones_(0), nrzi_(), crc_()
, input_(input), modulator_(output)
, running_(false), send_delay_(true)
{}
void run() {
running_ = true;
send_delay_ = true;
while (running_) {
state_ = state_type::STATE_IDLE;
osEvent evt = osMessageGet(input_, osWaitForever);
if (evt.status == osEventMessage) {
auto frame = (IoFrame*) evt.value.p;
process(frame);
// See if we have back-to-back frames.
evt = osMessagePeek(input_, 0);
if (evt.status != osEventMessage) {
send_delay_ = true;
if (!duplex_) {
osMessagePut(audioInputQueueHandle, audio::DEMODULATOR,
osWaitForever);
}
}
}
}
}
int tx_delay() const { return tx_delay_; }
void tx_delay(int ms) { tx_delay_ = ms; }
int tx_tail() const { return tx_tail_; }
void tx_tail(int ms) { tx_tail_ = ms; }
int slot_time() const { return slot_time_; }
void slot_time(int value) { slot_time_ = value; }
int p_persist() const { return p_persist_; }
void p_persist(int value) { p_persist_ = value; }
state_type status() const {return state_; }
void stop() { running_ = false; }
int rng_() const {return osKernelSysTick() & 0xFF;}
/**
* Do the p*persistent CSMA handling. In order to prevent resource
* starvation, we drop any packets delayed by more than 5 seconds.
*
* 0. CSMA called.
* 1. If the channel is open
* 1a. Pick a random number between 0-255.
* 1b. If it less than or equal to p, transmit the packet.
* 2. Otherwise wait slot_time * 10 ms.
* 2.b Go to step 1.
*
* In general, a p*persistent CSMA protocol should be adaptive. The
* p value should be dynamically computed based on network load. In
* practice, this is rather difficult to do with APRS because there
* is no easy way to measure the collision rate.
*
* For APRS digipeaters, the slot_time and p values should be 0 and 255,
* respectively. This is equivalent to 1-persistent CSMA.
*
2018-09-20 02:56:07 +00:00
* @pre The demodulator is running in order to detect the data carrier.
*
* @note For this to work, the demodulator must be left running
* while CSMA is taking place in order to do carrier detection.
*
* @return true if OK to send, otherwise CSMA has timed out and
* the packet should be dropped.
*/
bool do_csma() {
// Wait until we can transmit. If we cannot transmit for 10s
// drop the frame.
if (!dcd()) {
// Channel is clear... send now.
return true;
}
uint16_t counter = 0;
while (counter < 1000) {
osDelay(slot_time_ * 10); // We count on minimum delay = 1.
counter += slot_time_;
if (rng_() < p_persist_) {
if (!dcd()) {
// Channel is clear... send now.
return true;
}
}
}
return false;
}
/**
* Send the frame. If send_delay_ is set, we are sending the first
* of potentially multiple frames. We must do two things in this case:
* wait for the channel to clear and send the TX delay preamble.
* Otherwise, we are sending a follow-on frame and can skip the
* CSMA and preamble. The channel is ours and the begin/end frame
* bytes are enough to delimit the frames.
*
* If CSMA fails (times out), the frame is dropped and the send_delay_
* flag is not cleared. This will cause CSMA and TX delay to be
* attempted on the next frame.
*
2018-09-20 02:56:07 +00:00
* @pre either send_delay_ is false or the demodulator is running. We
* expect that send_delay_ is false only when we have back-to-back
* packets.
*
* @param frame
*/
void process(IoFrame* frame) {
ones_ = 0; // Reset the ones count for each frame.
frame->add_fcs();
if (send_delay_) {
2018-09-20 02:56:07 +00:00
if (not do_csma()) {
release(frame);
return;
}
if (!duplex_) {
osMessagePut(audioInputQueueHandle, audio::IDLE, osWaitForever);
}
send_delay();
send_delay_ = false;
}
for (auto c : *frame) send(c);
release(frame);
send_tail();
}
void send_delay() {
const size_t tmp = (tx_delay_ * 3) / 2;
for (size_t i = 0; i != tmp; i++) {
send_raw(FLAG);
}
}
void send_fcs(uint16_t fcs) {
uint8_t low = fcs & 0xFF;
uint8_t high = (fcs >> 8) & 0xFF;
send(low);
send(high);
}
void send_tail() {
send_raw(FLAG);
}
// No bit stuffing for PREAMBLE and TAIL
void send_raw(uint8_t byte) {
for (size_t i = 0; i != 8; i++) {
uint8_t bit = byte & 1;
modulator_->send(nrzi_.encode(bit));
byte >>= 1;
}
}
void send(uint8_t byte) {
for (size_t i = 0; i != 8; i++) {
uint8_t bit = byte & 1;
modulator_->send(nrzi_.encode(bit));
if (bit) {
++ones_;
if (ones_ == 5) {
modulator_->send(nrzi_.encode(0));
ones_ = 0;
}
} else {
ones_ = 0;
}
byte >>= 1;
}
}
};
}}} // mobilinkd::tnc::hdlc
#endif // INC_HDLCENCODER_HPP_