CubicSDR/src/demod/DemodulatorMgr.cpp

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// Copyright (c) Charles J. Cliffe
// SPDX-License-Identifier: GPL-2.0+
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#include <DemodulatorMgr.h>
#include <sstream>
#include <algorithm>
#include <string>
#include <sstream>
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#include <algorithm>
#include "DemodulatorMgr.h"
#include "CubicSDR.h"
#if USE_HAMLIB
#include "RigThread.h"
#endif
#include "DataTree.h"
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bool demodFreqCompare (DemodulatorInstance *i, DemodulatorInstance *j) { return (i->getFrequency()<j->getFrequency()); }
bool inactiveCompare (DemodulatorInstance *i, DemodulatorInstance *j) { return (i->isActive()<j->isActive()); }
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DemodulatorMgr::DemodulatorMgr() {
activeDemodulator = NULL;
lastActiveDemodulator = NULL;
activeVisualDemodulator = NULL;
lastBandwidth = DEFAULT_DEMOD_BW;
lastDemodType = DEFAULT_DEMOD_TYPE;
lastSquelchEnabled = false;
lastSquelch = -100;
lastGain = 1.0;
lastMuted = false;
lastDeltaLock = false;
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}
DemodulatorMgr::~DemodulatorMgr() {
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terminateAll();
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}
DemodulatorInstance *DemodulatorMgr::newThread() {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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DemodulatorInstance *newDemod = new DemodulatorInstance;
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std::stringstream label;
label << demods.size();
newDemod->setLabel(label.str());
demods.push_back(newDemod);
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return newDemod;
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}
void DemodulatorMgr::terminateAll() {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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while (demods.size()) {
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DemodulatorInstance *d = demods.back();
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demods.pop_back();
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wxGetApp().removeDemodulator(d);
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deleteThread(d);
}
}
std::vector<DemodulatorInstance *> &DemodulatorMgr::getDemodulators() {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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return demods;
}
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std::vector<DemodulatorInstance *> DemodulatorMgr::getOrderedDemodulators(bool actives) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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std::vector<DemodulatorInstance *> demods_ordered = demods;
if (actives) {
std::sort(demods_ordered.begin(), demods_ordered.end(), inactiveCompare);
std::vector<DemodulatorInstance *>::iterator i;
for (i = demods_ordered.begin(); i != demods_ordered.end(); i++) {
if ((*i)->isActive()) {
break;
}
}
if (i == demods_ordered.end()) {
demods_ordered.erase(demods_ordered.begin(), demods_ordered.end());
} else if ((*i) != demods_ordered.front()) {
demods_ordered.erase(demods_ordered.begin(), i);
}
}
//if by chance they have the same frequency, keep their relative order
std::stable_sort(demods_ordered.begin(), demods_ordered.end(), demodFreqCompare);
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return demods_ordered;
}
DemodulatorInstance *DemodulatorMgr::getPreviousDemodulator(DemodulatorInstance *demod, bool actives) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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if (!getLastActiveDemodulator()) {
return nullptr;
}
std::vector<DemodulatorInstance *> demods_ordered = getOrderedDemodulators(actives);
std::vector<DemodulatorInstance *>::iterator p = std::find(demods_ordered.begin(), demods_ordered.end(), demod);
if (p == demods_ordered.end()) {
return nullptr;
}
if (*p == demods_ordered.front()) {
return demods_ordered.back();
}
return *(--p);
}
DemodulatorInstance *DemodulatorMgr::getNextDemodulator(DemodulatorInstance *demod, bool actives) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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if (!getLastActiveDemodulator()) {
return nullptr;
}
std::vector<DemodulatorInstance *> demods_ordered = getOrderedDemodulators(actives);
std::vector<DemodulatorInstance *>::iterator p = std::find(demods_ordered.begin(), demods_ordered.end(), demod);
if (actives) {
}
if (p == demods_ordered.end()) {
return nullptr;
}
if (*p == demods_ordered.back()) {
return demods_ordered.front();
}
return *(++p);
}
DemodulatorInstance *DemodulatorMgr::getLastDemodulator() {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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std::vector<DemodulatorInstance *> demods_ordered = getOrderedDemodulators();
return *(demods_ordered.end());
}
DemodulatorInstance *DemodulatorMgr::getFirstDemodulator() {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
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std::vector<DemodulatorInstance *> demods_ordered = getOrderedDemodulators();
return *(demods_ordered.begin());
}
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void DemodulatorMgr::deleteThread(DemodulatorInstance *demod) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
wxGetApp().getBookmarkMgr().addRecent(demod);
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std::vector<DemodulatorInstance *>::iterator i;
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i = std::find(demods.begin(), demods.end(), demod);
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if (activeDemodulator == demod) {
activeDemodulator = nullptr;
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}
if (lastActiveDemodulator == demod) {
lastActiveDemodulator = nullptr;
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}
if (activeVisualDemodulator == demod) {
activeVisualDemodulator = nullptr;
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}
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if (i != demods.end()) {
demods.erase(i);
}
//Ask for termination
demod->setActive(false);
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demod->terminate();
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//Do not cleanup immediatly
std::lock_guard < std::mutex > lock_deleted(deleted_demods_busy);
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demods_deleted.push_back(demod);
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}
std::vector<DemodulatorInstance *> DemodulatorMgr::getDemodulatorsAt(long long freq, int bandwidth) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
std::vector<DemodulatorInstance *> foundDemods;
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for (int i = 0, iMax = demods.size(); i < iMax; i++) {
DemodulatorInstance *testDemod = demods[i];
long long freqTest = testDemod->getFrequency();
long long bandwidthTest = testDemod->getBandwidth();
long long halfBandwidthTest = bandwidthTest / 2;
long long halfBuffer = bandwidth / 2;
if ((freq <= (freqTest + ((testDemod->getDemodulatorType() != "LSB")?halfBandwidthTest:0) + halfBuffer)) && (freq >= (freqTest - ((testDemod->getDemodulatorType() != "USB")?halfBandwidthTest:0) - halfBuffer))) {
foundDemods.push_back(testDemod);
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}
}
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return foundDemods;
}
bool DemodulatorMgr::anyDemodulatorsAt(long long freq, int bandwidth) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
for (int i = 0, iMax = demods.size(); i < iMax; i++) {
DemodulatorInstance *testDemod = demods[i];
long long freqTest = testDemod->getFrequency();
long long bandwidthTest = testDemod->getBandwidth();
long long halfBandwidthTest = bandwidthTest / 2;
long long halfBuffer = bandwidth / 2;
if ((freq <= (freqTest + ((testDemod->getDemodulatorType() != "LSB")?halfBandwidthTest:0) + halfBuffer)) && (freq >= (freqTest - ((testDemod->getDemodulatorType() != "USB")?halfBandwidthTest:0) - halfBuffer))) {
return true;
}
}
return false;
}
void DemodulatorMgr::setActiveDemodulator(DemodulatorInstance *demod, bool temporary) {
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if (!temporary) {
if (activeDemodulator.load() != nullptr) {
lastActiveDemodulator = activeDemodulator.load();
updateLastState();
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} else {
lastActiveDemodulator = demod;
}
updateLastState();
#if USE_HAMLIB
if (wxGetApp().rigIsActive() && wxGetApp().getRigThread()->getFollowModem() && lastActiveDemodulator.load()) {
wxGetApp().getRigThread()->setFrequency(lastActiveDemodulator.load()->getFrequency(),true);
}
#endif
wxGetApp().getBookmarkMgr().updateActiveList();
}
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if (activeVisualDemodulator.load()) {
activeVisualDemodulator.load()->setVisualOutputQueue(nullptr);
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}
if (demod) {
demod->setVisualOutputQueue(wxGetApp().getAudioVisualQueue());
activeVisualDemodulator = demod;
} else {
DemodulatorInstance *last = getLastActiveDemodulator();
if (last) {
last->setVisualOutputQueue(wxGetApp().getAudioVisualQueue());
}
activeVisualDemodulator = last;
}
activeDemodulator = demod;
}
DemodulatorInstance *DemodulatorMgr::getActiveDemodulator() {
if (activeDemodulator.load() && !activeDemodulator.load()->isActive()) {
activeDemodulator = getLastActiveDemodulator();
}
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return activeDemodulator;
}
DemodulatorInstance *DemodulatorMgr::getLastActiveDemodulator() {
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return lastActiveDemodulator;
}
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DemodulatorInstance *DemodulatorMgr::getLastDemodulatorWith(const std::string& type,
const std::wstring& userLabel,
long long frequency,
int bandwidth) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
//backwards search:
for (std::vector<DemodulatorInstance *>::reverse_iterator it = demods.rbegin(); it != demods.rend(); it++) {
if ((*it)->getDemodulatorType() == type &&
(*it)->getDemodulatorUserLabel() == userLabel &&
(*it)->getFrequency() == frequency &&
(*it)->getBandwidth() == bandwidth) {
return (*it);
}
}
return nullptr;
}
void DemodulatorMgr::garbageCollect(bool forcedGC) {
std::lock_guard < std::mutex > lock(deleted_demods_busy);
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while (!demods_deleted.empty()) {
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std::vector<DemodulatorInstance *>::iterator it = demods_deleted.begin();
//make 1 pass over
while (it != demods_deleted.end()) {
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if ((*it)->isTerminated()) {
DemodulatorInstance *deleted = (*it);
std::cout << "Garbage collected demodulator instance '" << deleted->getLabel() << "'... " << std::endl << std::flush;
it = demods_deleted.erase(it);
delete deleted;
//only garbage collect 1 demod at a time.
if (!forcedGC) {
return;
}
}
else {
it++;
}
} //end while
//stupid busy-wait loop
std::this_thread::sleep_for(std::chrono::milliseconds(5));
} //end while not empty
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}
void DemodulatorMgr::updateLastState() {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
if (std::find(demods.begin(), demods.end(), lastActiveDemodulator) == demods.end()) {
if (activeDemodulator.load() && activeDemodulator.load()->isActive()) {
lastActiveDemodulator = activeDemodulator.load();
} else if (activeDemodulator.load() && !activeDemodulator.load()->isActive()){
activeDemodulator = nullptr;
lastActiveDemodulator = nullptr;
}
}
if (lastActiveDemodulator.load() && !lastActiveDemodulator.load()->isActive()) {
lastActiveDemodulator = nullptr;
}
if (lastActiveDemodulator.load()) {
lastBandwidth = lastActiveDemodulator.load()->getBandwidth();
lastDemodType = lastActiveDemodulator.load()->getDemodulatorType();
lastDemodLock = lastActiveDemodulator.load()->getDemodulatorLock()?true:false;
lastSquelchEnabled = lastActiveDemodulator.load()->isSquelchEnabled();
lastSquelch = lastActiveDemodulator.load()->getSquelchLevel();
lastGain = lastActiveDemodulator.load()->getGain();
lastModemSettings[lastDemodType] = lastActiveDemodulator.load()->readModemSettings();
}
}
int DemodulatorMgr::getLastBandwidth() const {
return lastBandwidth;
}
void DemodulatorMgr::setLastBandwidth(int lastBandwidth) {
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if (lastBandwidth < MIN_BANDWIDTH) {
lastBandwidth = MIN_BANDWIDTH;
} else if (lastBandwidth > wxGetApp().getSampleRate()) {
lastBandwidth = wxGetApp().getSampleRate();
}
this->lastBandwidth = lastBandwidth;
}
std::string DemodulatorMgr::getLastDemodulatorType() const {
return lastDemodType;
}
void DemodulatorMgr::setLastDemodulatorType(std::string lastDemodType) {
this->lastDemodType = lastDemodType;
}
float DemodulatorMgr::getLastGain() const {
return lastGain;
}
void DemodulatorMgr::setLastGain(float lastGain) {
this->lastGain = lastGain;
}
bool DemodulatorMgr::getLastDeltaLock() const {
return lastDeltaLock;
}
void DemodulatorMgr::setLastDeltaLock(bool lock) {
lastDeltaLock = lock;
}
float DemodulatorMgr::getLastSquelchLevel() const {
return lastSquelch;
}
void DemodulatorMgr::setLastSquelchLevel(float lastSquelch) {
this->lastSquelch = lastSquelch;
}
bool DemodulatorMgr::isLastSquelchEnabled() const {
return lastSquelchEnabled;
}
void DemodulatorMgr::setLastSquelchEnabled(bool lastSquelchEnabled) {
this->lastSquelchEnabled = lastSquelchEnabled;
}
bool DemodulatorMgr::isLastMuted() const {
return lastMuted;
}
void DemodulatorMgr::setLastMuted(bool lastMuted) {
this->lastMuted = lastMuted;
}
ModemSettings DemodulatorMgr::getLastModemSettings(std::string modemType) {
return lastModemSettings[modemType];
}
void DemodulatorMgr::setLastModemSettings(std::string modemType, ModemSettings settings) {
lastModemSettings[modemType] = settings;
}
void DemodulatorMgr::setOutputDevices(std::map<int,RtAudio::DeviceInfo> devs) {
outputDevices = devs;
}
void DemodulatorMgr::saveInstance(DataNode *node, DemodulatorInstance *inst) {
*node->newChild("bandwidth") = inst->getBandwidth();
*node->newChild("frequency") = inst->getFrequency();
*node->newChild("type") = inst->getDemodulatorType();
node->newChild("user_label")->element()->set(inst->getDemodulatorUserLabel());
*node->newChild("squelch_level") = inst->getSquelchLevel();
*node->newChild("squelch_enabled") = inst->isSquelchEnabled() ? 1 : 0;
*node->newChild("output_device") = outputDevices[inst->getOutputDevice()].name;
*node->newChild("gain") = inst->getGain();
*node->newChild("muted") = inst->isMuted() ? 1 : 0;
if (inst->isDeltaLock()) {
*node->newChild("delta_lock") = inst->isDeltaLock() ? 1 : 0;
*node->newChild("delta_ofs") = inst->getDeltaLockOfs();
}
if (inst == getLastActiveDemodulator()) {
*node->newChild("active") = 1;
}
ModemSettings saveSettings = inst->readModemSettings();
if (saveSettings.size()) {
DataNode *settingsNode = node->newChild("settings");
for (ModemSettings::const_iterator msi = saveSettings.begin(); msi != saveSettings.end(); msi++) {
*settingsNode->newChild(msi->first.c_str()) = msi->second;
}
}
}
DemodulatorInstance *DemodulatorMgr::loadInstance(DataNode *node) {
std::lock_guard < std::recursive_mutex > lock(demods_busy);
DemodulatorInstance *newDemod = nullptr;
node->rewindAll();
long bandwidth = *node->getNext("bandwidth");
long long freq = *node->getNext("frequency");
float squelch_level = node->hasAnother("squelch_level") ? (float) *node->getNext("squelch_level") : 0;
int squelch_enabled = node->hasAnother("squelch_enabled") ? (int) *node->getNext("squelch_enabled") : 0;
int muted = node->hasAnother("muted") ? (int) *node->getNext("muted") : 0;
int delta_locked = node->hasAnother("delta_lock") ? (int) *node->getNext("delta_lock") : 0;
int delta_ofs = node->hasAnother("delta_ofs") ? (int) *node->getNext("delta_ofs") : 0;
std::string output_device = node->hasAnother("output_device") ? string(*(node->getNext("output_device"))) : "";
float gain = node->hasAnother("gain") ? (float) *node->getNext("gain") : 1.0;
std::string type = "FM";
DataNode *demodTypeNode = node->hasAnother("type")?node->getNext("type"):nullptr;
if (demodTypeNode && demodTypeNode->element()->getDataType() == DATA_INT) {
int legacyType = *demodTypeNode;
int legacyStereo = node->hasAnother("stereo") ? (int) *node->getNext("stereo") : 0;
switch (legacyType) { // legacy demod ID
case 1: type = legacyStereo?"FMS":"FM"; break;
case 2: type = "AM"; break;
case 3: type = "LSB"; break;
case 4: type = "USB"; break;
case 5: type = "DSB"; break;
case 6: type = "ASK"; break;
case 7: type = "APSK"; break;
case 8: type = "BPSK"; break;
case 9: type = "DPSK"; break;
case 10: type = "PSK"; break;
case 11: type = "OOK"; break;
case 12: type = "ST"; break;
case 13: type = "SQAM"; break;
case 14: type = "QAM"; break;
case 15: type = "QPSK"; break;
case 16: type = "I/Q"; break;
default: type = "FM"; break;
}
} else if (demodTypeNode && demodTypeNode->element()->getDataType() == DATA_STRING) {
demodTypeNode->element()->get(type);
}
//read the user label associated with the demodulator
std::wstring user_label = L"";
DataNode *demodUserLabel = node->hasAnother("user_label") ? node->getNext("user_label") : nullptr;
if (demodUserLabel) {
demodUserLabel->element()->get(user_label);
}
ModemSettings mSettings;
if (node->hasAnother("settings")) {
DataNode *modemSettings = node->getNext("settings");
for (int msi = 0, numSettings = modemSettings->numChildren(); msi < numSettings; msi++) {
DataNode *settingNode = modemSettings->child(msi);
std::string keyName = settingNode->getName();
std::string strSettingValue = settingNode->element()->toString();
if (keyName != "" && strSettingValue != "") {
mSettings[keyName] = strSettingValue;
}
}
}
newDemod = newThread();
newDemod->setDemodulatorType(type);
newDemod->setDemodulatorUserLabel(user_label);
newDemod->writeModemSettings(mSettings);
newDemod->setBandwidth(bandwidth);
newDemod->setFrequency(freq);
newDemod->setGain(gain);
newDemod->updateLabel(freq);
newDemod->setMuted(muted?true:false);
if (delta_locked) {
newDemod->setDeltaLock(true);
newDemod->setDeltaLockOfs(delta_ofs);
}
if (squelch_enabled) {
newDemod->setSquelchEnabled(true);
newDemod->setSquelchLevel(squelch_level);
}
//Attach to sound output:
std::map<int, RtAudio::DeviceInfo>::iterator i;
for (i = outputDevices.begin(); i != outputDevices.end(); i++) {
if (i->second.name == output_device) {
newDemod->setOutputDevice(i->first);
break;
}
}
return newDemod;
}