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LibrePilot/flight/Modules/Radio/radio.c

551 lines
16 KiB
C

/**
******************************************************************************
* @addtogroup OpenPilotModules OpenPilot Modules
* @{
* @addtogroup Radio Input / Output Module
* @brief Read and Write packets from/to a radio device.
* @{
*
* @file radio.c
* @author The OpenPilot Team, http://www.openpilot.org Copyright (C) 2012.
* @brief Bridges selected Com Port to the COM VCP emulated serial port
* @see The GNU Public License (GPL) Version 3
*
*****************************************************************************/
/*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include <openpilot.h>
#include <gcsreceiver.h>
#include <hwsettings.h>
#include <pipxsettings.h>
#include <pipxstatus.h>
#include <packet_handler.h>
#include <pios_com_priv.h>
#include <pios_rfm22b_priv.h>
#include <radio.h>
// ****************
// Private constants
#define STACK_SIZE_BYTES 150
#define TASK_PRIORITY (tskIDLE_PRIORITY + 2)
#define PACKET_QUEUE_SIZE PIOS_PH_WIN_SIZE
#define MAX_PORT_DELAY 200
#define STATS_UPDATE_PERIOD_MS 500
#define RADIOSTATS_UPDATE_PERIOD_MS 250
#define MAX_LOST_CONTACT_TIME 4
#ifndef LINK_LED_ON
#define LINK_LED_ON
#define LINK_LED_OFF
#endif
// ****************
// Private types
typedef struct {
uint32_t pairID;
uint16_t retries;
uint16_t errors;
uint16_t uavtalk_errors;
uint16_t resets;
uint16_t dropped;
int8_t rssi;
uint8_t lastContact;
} PairStats;
typedef struct {
// The task handles.
xTaskHandle radioReceiveTaskHandle;
xTaskHandle radioStatusTaskHandle;
xTaskHandle sendPacketTaskHandle;
// Queue handles.
xQueueHandle radioPacketQueue;
// Error statistics.
uint32_t radioTxErrors;
uint32_t radioRxErrors;
uint32_t packetErrors;
uint16_t txBytes;
uint16_t rxBytes;
// External error statistics
uint32_t droppedPackets;
uint32_t comTxRetries;
uint32_t UAVTalkErrors;
// The destination ID
uint32_t destination_id;
// Track other radios that are in range.
PairStats pairStats[PIPXSTATUS_PAIRIDS_NUMELEM];
// The RSSI of the last packet received.
int8_t RSSI;
} RadioData;
// ****************
// Private functions
static void radioReceiveTask(void *parameters);
static void radioStatusTask(void *parameters);
static void sendPacketTask(void *parameters);
static void StatusHandler(PHStatusPacketHandle p, int8_t rssi, int8_t afc);
static int32_t transmitPacket(PHPacketHandle packet);
static void PPMHandler(uint16_t *channels);
// ****************
// Private variables
static RadioData *data = 0;
// ****************
// Global variables
uint32_t pios_rfm22b_id = 0;
uint32_t pios_com_rfm22b_id = 0;
uint32_t pios_packet_handler = 0;
extern struct pios_rfm22b_cfg pios_rfm22b_cfg;
/**
* Start the module
* \return -1 if initialisation failed
* \return 0 on success
*/
static int32_t RadioStart(void)
{
if (!data)
return -1;
// Start the tasks.
xTaskCreate(radioReceiveTask, (signed char *)"RadioReceive", STACK_SIZE_BYTES, NULL, TASK_PRIORITY, &(data->radioReceiveTaskHandle));
xTaskCreate(radioStatusTask, (signed char *)"RadioStatus", STACK_SIZE_BYTES * 2, NULL, TASK_PRIORITY, &(data->radioStatusTaskHandle));
xTaskCreate(sendPacketTask, (signed char *)"SendPacket", STACK_SIZE_BYTES, NULL, TASK_PRIORITY, &(data->sendPacketTaskHandle));
// Install the monitors
TaskMonitorAdd(TASKINFO_RUNNING_MODEMRX, data->radioReceiveTaskHandle);
TaskMonitorAdd(TASKINFO_RUNNING_MODEMTX, data->sendPacketTaskHandle);
TaskMonitorAdd(TASKINFO_RUNNING_MODEMSTAT, data->radioStatusTaskHandle);
// Register the watchdog timers.
#ifdef PIOS_WDG_RADIORECEIVE
PIOS_WDG_RegisterFlag(PIOS_WDG_RADIORECEIVE);
#endif /* PIOS_WDG_RADIORECEIVE */
return 0;
}
/**
* Initialise the module
* \return -1 if initialisation failed
* \return 0 on success
*/
static int32_t RadioInitialize(void)
{
// See if this module is enabled.
#ifndef RADIO_BUILTIN
HwSettingsInitialize();
uint8_t optionalModules[HWSETTINGS_OPTIONALMODULES_NUMELEM];
HwSettingsOptionalModulesGet(optionalModules);
if (optionalModules[HWSETTINGS_OPTIONALMODULES_RADIO] != HWSETTINGS_OPTIONALMODULES_ENABLED)
return -1;
#endif
// Initalize out UAVOs
PipXSettingsInitialize();
PipXStatusInitialize();
PipXSettingsData pipxSettings;
PipXSettingsGet(&pipxSettings);
/* Retrieve hardware settings. */
pios_rfm22b_cfg.frequencyHz = pipxSettings.Frequency;
pios_rfm22b_cfg.RFXtalCap = pipxSettings.FrequencyCalibration;
switch (pipxSettings.RFSpeed)
{
case PIPXSETTINGS_RFSPEED_2400:
pios_rfm22b_cfg.maxRFBandwidth = 2000;
break;
case PIPXSETTINGS_RFSPEED_4800:
pios_rfm22b_cfg.maxRFBandwidth = 4000;
break;
case PIPXSETTINGS_RFSPEED_9600:
pios_rfm22b_cfg.maxRFBandwidth = 9600;
break;
case PIPXSETTINGS_RFSPEED_19200:
pios_rfm22b_cfg.maxRFBandwidth = 19200;
break;
case PIPXSETTINGS_RFSPEED_38400:
pios_rfm22b_cfg.maxRFBandwidth = 32000;
break;
case PIPXSETTINGS_RFSPEED_57600:
pios_rfm22b_cfg.maxRFBandwidth = 64000;
break;
case PIPXSETTINGS_RFSPEED_115200:
pios_rfm22b_cfg.maxRFBandwidth = 128000;
break;
}
switch (pipxSettings.MaxRFPower)
{
case PIPXSETTINGS_MAXRFPOWER_125:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_0;
break;
case PIPXSETTINGS_MAXRFPOWER_16:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_1;
break;
case PIPXSETTINGS_MAXRFPOWER_316:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_2;
break;
case PIPXSETTINGS_MAXRFPOWER_63:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_3;
break;
case PIPXSETTINGS_MAXRFPOWER_126:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_4;
break;
case PIPXSETTINGS_MAXRFPOWER_25:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_5;
break;
case PIPXSETTINGS_MAXRFPOWER_50:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_6;
break;
case PIPXSETTINGS_MAXRFPOWER_100:
pios_rfm22b_cfg.maxTxPower = RFM22_tx_pwr_txpow_7;
break;
}
/* Initalize the RFM22B radio COM device. */
{
if (PIOS_RFM22B_Init(&pios_rfm22b_id, PIOS_RFM22_SPI_PORT, pios_rfm22b_cfg.slave_num, &pios_rfm22b_cfg)) {
return -1;
}
uint8_t * rx_buffer = (uint8_t *) pvPortMalloc(PIOS_COM_RFM22B_RF_RX_BUF_LEN);
uint8_t * tx_buffer = (uint8_t *) pvPortMalloc(PIOS_COM_RFM22B_RF_TX_BUF_LEN);
PIOS_Assert(rx_buffer);
PIOS_Assert(tx_buffer);
if (PIOS_COM_Init(&pios_com_rfm22b_id, &pios_rfm22b_com_driver, pios_rfm22b_id,
rx_buffer, PIOS_COM_RFM22B_RF_RX_BUF_LEN,
tx_buffer, PIOS_COM_RFM22B_RF_TX_BUF_LEN)) {
PIOS_Assert(0);
}
}
// Initialize the packet handler
PacketHandlerConfig pios_ph_cfg = {
.default_destination_id = 0xffffffff, // Broadcast
.source_id = PIOS_RFM22B_DeviceID(pios_rfm22b_id),
.win_size = PIOS_PH_WIN_SIZE,
.max_connections = PIOS_PH_MAX_CONNECTIONS,
};
pios_packet_handler = PHInitialize(&pios_ph_cfg);
// allocate and initialize the static data storage only if module is enabled
data = (RadioData *)pvPortMalloc(sizeof(RadioData));
if (!data)
return -1;
// Initialize the statistics.
data->radioTxErrors = 0;
data->radioRxErrors = 0;
data->packetErrors = 0;
data->droppedPackets = 0;
data->comTxRetries = 0;
data->UAVTalkErrors = 0;
data->RSSI = -127;
// Initialize the detected device statistics.
for (uint8_t i = 0; i < PIPXSTATUS_PAIRIDS_NUMELEM; ++i)
{
data->pairStats[i].pairID = 0;
data->pairStats[i].rssi = -127;
data->pairStats[i].retries = 0;
data->pairStats[i].errors = 0;
data->pairStats[i].uavtalk_errors = 0;
data->pairStats[i].resets = 0;
data->pairStats[i].dropped = 0;
data->pairStats[i].lastContact = 0;
}
// The first slot is reserved for our current pairID
PipXSettingsPairIDGet(&(data->pairStats[0].pairID));
data->destination_id = data->pairStats[0].pairID ? data->pairStats[0].pairID : 0xffffffff;
// Create the packet queue.
data->radioPacketQueue = xQueueCreate(PACKET_QUEUE_SIZE, sizeof(PHPacketHandle));
// Register the callbacks with the packet handler
PHRegisterStatusHandler(pios_packet_handler, StatusHandler);
PHRegisterOutputStream(pios_packet_handler, transmitPacket);
PHRegisterPPMHandler(pios_packet_handler, PPMHandler);
return 0;
}
MODULE_INITCALL(RadioInitialize, RadioStart)
/**
* The task that receives packets from the radio.
*/
static void radioReceiveTask(void *parameters)
{
PHPacketHandle p = NULL;
/* Handle radio -> usart/usb direction */
while (1) {
uint32_t rx_bytes;
#ifdef PIOS_WDG_RADIORECEIVE
// Update the watchdog timer.
PIOS_WDG_UpdateFlag(PIOS_WDG_RADIORECEIVE);
#endif /* PIOS_INCLUDE_WDG */
// Get a RX packet from the packet handler if required.
if (p == NULL)
p = PHGetRXPacket(pios_packet_handler);
if(p == NULL) {
// Wait a bit for a packet to come available.
vTaskDelay(5);
continue;
}
// Receive data from the radio port
rx_bytes = PIOS_COM_ReceiveBuffer(PIOS_COM_RADIO, (uint8_t*)p, PIOS_PH_MAX_PACKET, MAX_PORT_DELAY);
if(rx_bytes == 0)
continue;
data->rxBytes += rx_bytes;
// Verify that the packet is valid and pass it on.
bool rx_error = PHVerifyPacket(pios_packet_handler, p, rx_bytes) < 0;
if(rx_error)
data->packetErrors++;
PHReceivePacket(pios_packet_handler, p, rx_error);
p = NULL;
}
}
/**
* Send packets to the radio.
*/
static void sendPacketTask(void *parameters)
{
PHPacketHandle p;
// Loop forever
while (1) {
#ifdef PIOS_INCLUDE_WDG
// Update the watchdog timer.
//PIOS_WDG_UpdateFlag(PIOS_WDG_SENDPACKET);
#endif /* PIOS_INCLUDE_WDG */
// Wait for a packet on the queue.
if (xQueueReceive(data->radioPacketQueue, &p, MAX_PORT_DELAY) == pdTRUE) {
PIOS_COM_SendBuffer(PIOS_COM_RADIO, (uint8_t*)p, PH_PACKET_SIZE(p));
PHReleaseTXPacket(pios_packet_handler, p);
}
}
}
/**
* Transmit a packet to the radio port.
* \param[in] buf Data buffer to send
* \param[in] length Length of buffer
* \return -1 on failure
* \return number of bytes transmitted on success
*/
static int32_t transmitPacket(PHPacketHandle p)
{
uint16_t len = PH_PACKET_SIZE(p);
data->txBytes += len;
if (xQueueSend(data->radioPacketQueue, &p, portMAX_DELAY) != pdTRUE)
return -1;
return len;
}
/**
* Receive a status packet
* \param[in] status The status structure
*/
static void StatusHandler(PHStatusPacketHandle status, int8_t rssi, int8_t afc)
{
uint32_t id = status->header.source_id;
bool found = false;
// Have we seen this device recently?
uint8_t id_idx = 0;
for ( ; id_idx < PIPXSTATUS_PAIRIDS_NUMELEM; ++id_idx)
if(data->pairStats[id_idx].pairID == id)
{
found = true;
break;
}
// If we have seen it, update the RSSI and reset the last contact couter
if(found)
{
data->pairStats[id_idx].rssi = rssi;
data->pairStats[id_idx].retries = status->retries;
data->pairStats[id_idx].errors = status->errors;
data->pairStats[id_idx].uavtalk_errors = status->uavtalk_errors;
data->pairStats[id_idx].resets = status->resets;
data->pairStats[id_idx].dropped = status->dropped;
data->pairStats[id_idx].lastContact = 0;
}
// If we haven't seen it, find a slot to put it in.
if (!found)
{
uint32_t pairID;
PipXSettingsPairIDGet(&pairID);
uint8_t min_idx = 0;
if(id != pairID)
{
int8_t min_rssi = data->pairStats[0].rssi;
for (id_idx = 1; id_idx < PIPXSTATUS_PAIRIDS_NUMELEM; ++id_idx)
{
if(data->pairStats[id_idx].rssi < min_rssi)
{
min_rssi = data->pairStats[id_idx].rssi;
min_idx = id_idx;
}
}
}
data->pairStats[min_idx].pairID = id;
data->pairStats[min_idx].rssi = rssi;
data->pairStats[min_idx].retries = status->retries;
data->pairStats[min_idx].errors = status->errors;
data->pairStats[min_idx].uavtalk_errors = status->uavtalk_errors;
data->pairStats[min_idx].resets = status->resets;
data->pairStats[min_idx].dropped = status->dropped;
data->pairStats[min_idx].lastContact = 0;
}
}
/**
* The stats update task.
*/
static void radioStatusTask(void *parameters)
{
static portTickType lastSysTime;
PHStatusPacket status_packet;
while (1) {
lastSysTime = xTaskGetTickCount();
PipXStatusData pipxStatus;
uint32_t pairID;
// Get object data
PipXStatusGet(&pipxStatus);
PipXSettingsPairIDGet(&pairID);
// Update the status
pipxStatus.DeviceID = PIOS_RFM22B_DeviceID(pios_rfm22b_id);
pipxStatus.Retries = data->comTxRetries;
pipxStatus.Errors = data->packetErrors;
pipxStatus.UAVTalkErrors = data->UAVTalkErrors;
pipxStatus.Dropped = data->droppedPackets;
pipxStatus.Resets = PIOS_RFM22B_Resets(pios_rfm22b_id);
pipxStatus.TXRate = (uint16_t)((float)(data->txBytes * 1000) / STATS_UPDATE_PERIOD_MS);
data->txBytes = 0;
pipxStatus.RXRate = (uint16_t)((float)(data->rxBytes * 1000) / STATS_UPDATE_PERIOD_MS);
data->rxBytes = 0;
pipxStatus.LinkState = PIPXSTATUS_LINKSTATE_DISCONNECTED;
pipxStatus.RSSI = data->RSSI;
LINK_LED_OFF;
// Update the potential pairing contacts
for (uint8_t i = 0; i < PIPXSTATUS_PAIRIDS_NUMELEM; ++i)
{
pipxStatus.PairIDs[i] = data->pairStats[i].pairID;
pipxStatus.PairSignalStrengths[i] = data->pairStats[i].rssi;
data->pairStats[i].lastContact++;
// Remove this device if it's stale.
if(data->pairStats[i].lastContact > MAX_LOST_CONTACT_TIME)
{
data->pairStats[i].pairID = 0;
data->pairStats[i].rssi = -127;
data->pairStats[i].retries = 0;
data->pairStats[i].errors = 0;
data->pairStats[i].uavtalk_errors = 0;
data->pairStats[i].resets = 0;
data->pairStats[i].dropped = 0;
data->pairStats[i].lastContact = 0;
}
// Add the paired devices statistics to ours.
if(pairID && (data->pairStats[i].pairID == pairID) && (data->pairStats[i].rssi > -127))
{
pipxStatus.Retries += data->pairStats[i].retries;
pipxStatus.Errors += data->pairStats[i].errors;
pipxStatus.UAVTalkErrors += data->pairStats[i].uavtalk_errors;
pipxStatus.Dropped += data->pairStats[i].dropped;
pipxStatus.Resets += data->pairStats[i].resets;
pipxStatus.Dropped += data->pairStats[i].dropped;
pipxStatus.LinkState = PIPXSTATUS_LINKSTATE_CONNECTED;
LINK_LED_ON;
}
}
// Update the object
PipXStatusSet(&pipxStatus);
// Broadcast the status.
{
static uint16_t cntr = 0;
if(cntr++ == RADIOSTATS_UPDATE_PERIOD_MS / STATS_UPDATE_PERIOD_MS)
{
// Queue the status message
status_packet.header.destination_id = 0xffffffff;
status_packet.header.type = PACKET_TYPE_STATUS;
status_packet.header.data_size = PH_STATUS_DATA_SIZE(&status_packet);
status_packet.header.source_id = pipxStatus.DeviceID;
status_packet.retries = data->comTxRetries;
status_packet.errors = data->packetErrors;
status_packet.uavtalk_errors = data->UAVTalkErrors;
status_packet.dropped = data->droppedPackets;
status_packet.resets = PIOS_RFM22B_Resets(pios_rfm22b_id);
PHPacketHandle sph = (PHPacketHandle)&status_packet;
PHTransmitPacket(PIOS_PACKET_HANDLER, sph);
cntr = 0;
}
}
portTickType timeSinceUpdate;
do {
PIOS_RFM22_processPendingISR(5);
timeSinceUpdate = xTaskGetTickCount() - lastSysTime;
}
while(timeSinceUpdate < STATS_UPDATE_PERIOD_MS / portTICK_RATE_MS);
}
}
/**
* Receive a ppm packet
* \param[in] channels The ppm channels
*/
static void PPMHandler(uint16_t *channels)
{
GCSReceiverData rcvr;
// Copy the receiver channels into the GCSReceiver object.
for (uint8_t i = 0; i < GCSRECEIVER_CHANNEL_NUMELEM; ++i)
rcvr.Channel[i] = channels[i];
// Set the GCSReceiverData object.
GCSReceiverSet(&rcvr);
}