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sdrangel/plugins/samplesource/sdrdaemon/sdrdaemonbuffer.h
2017-05-25 20:13:34 +02:00

180 lines
8.3 KiB
C++

///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2016 Edouard Griffiths, F4EXB //
// //
// 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 as version 3 of the License, or //
// //
// 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 V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see <http://www.gnu.org/licenses/>. //
///////////////////////////////////////////////////////////////////////////////////
#ifndef PLUGINS_SAMPLESOURCE_SDRDAEMON_SDRDAEMONBUFFER_H_
#define PLUGINS_SAMPLESOURCE_SDRDAEMON_SDRDAEMONBUFFER_H_
#include <QString>
#include <cstdlib>
#include "util/CRC64.h"
class SDRdaemonBuffer
{
public:
public:
#pragma pack(push, 1)
struct MetaData
{
// critical data
uint32_t m_centerFrequency; //!< center frequency in kHz
uint32_t m_sampleRate; //!< sample rate in Hz
uint8_t m_sampleBytes; //!< MSB(4): indicators, LSB(4) number of bytes per sample
uint8_t m_sampleBits; //!< number of effective bits per sample
uint16_t m_blockSize; //!< payload size
uint32_t m_nbSamples; //!< number of samples in a hardware block
// end of critical data
uint16_t m_nbBlocks; //!< number of hardware blocks in the frame
uint32_t m_nbBytes; //!< total number of bytes in the frame
uint32_t m_tv_sec; //!< seconds of timestamp at start time of frame processing
uint32_t m_tv_usec; //!< microseconds of timestamp at start time of frame processing
uint64_t m_crc; //!< 64 bit CRC of the above
bool operator==(const MetaData& rhs)
{
return (memcmp((const void *) this, (const void *) &rhs, 20) == 0); // Only the 20 first bytes are relevant (critical)
}
void init()
{
memset((void *) this, 0, sizeof(MetaData));
}
void operator=(const MetaData& rhs)
{
memcpy((void *) this, (const void *) &rhs, sizeof(MetaData));
}
};
#pragma pack(pop)
SDRdaemonBuffer(uint32_t throttlems);
~SDRdaemonBuffer();
bool readMeta(char *array); //!< Attempt to read meta. Returns true if meta block
void writeData(char *array, uint32_t length); //!< Write data into buffer.
uint8_t *readData(int32_t length);
void updateBlockCounts(uint32_t nbBytesReceived);
const MetaData& getCurrentMeta() const { return m_currentMeta; }
uint32_t getSampleRateStream() const { return m_sampleRateStream; }
uint32_t getSampleRate() const { return m_sampleRate; }
bool isSync() const { return m_sync; }
bool isSyncLocked() const { return m_syncLock; }
uint32_t getFrameSize() const { return m_frameSize; }
bool isLz4Compressed() const { return m_lz4; }
float getCompressionRatio() const { return (m_frameSize > 0 ? (float) m_lz4InSize / (float) m_frameSize : 1.0); }
uint32_t getLz4DataCRCOK() const { return m_nbLastLz4CRCOK; }
uint32_t getLz4SuccessfulDecodes() const { return m_nbLastLz4SuccessfulDecodes; }
float getBufferLengthInSecs() const { return m_bufferLenSec; }
void setAutoFollowRate(bool autoFollowRate) { m_autoFollowRate = autoFollowRate; }
void setAutoCorrBuffer(bool autoCorrBuffer) { m_autoCorrBuffer = autoCorrBuffer; }
void setResetIndexes() { m_resetIndexes = true; }
int32_t getRWBalanceCorrection() const { return m_balCorrection; }
/** Get buffer gauge value in % of buffer size ([-50:50])
* [-50:0] : write leads or read lags
* [0:50] : read leads or write lags
*/
inline int32_t getBufferGauge() const
{
if (m_rawSize)
{
int32_t val = ((m_writeIndex - m_readIndex) * 100) / (int32_t) m_rawSize;
if (val < -50) {
return val + 100; // read leads (positive)
} else if (val < 50) {
return val; // read leads (positive) or write leads (negative)
} else {
return val - 100; // write leads (negative)
}
}
else
{
return -50; // default position
}
}
static const int m_udpPayloadSize;
static const int m_sampleSize;
static const int m_iqSampleSize;
static const int m_rawBufferLengthSeconds;
static const int m_rawBufferMinNbFrames; //!< Minimum number of frames for the length of buffer
private:
void updateBufferSize(uint32_t sampleRate);
void updateLZ4Sizes(uint32_t frameSize);
void updateReadBufferSize(uint32_t length);
void writeDataLZ4(const char *array, int length);
void writeToRawBufferLZ4();
void writeToRawBufferUncompressed(const char *array, int length);
void resetIndexes();
static void printMeta(const QString& header, MetaData *metaData);
uint32_t m_throttlemsNominal; //!< Initial throttle in ms
int m_rawSize; //!< Size of the raw samples buffer in bytes
uint8_t *m_rawBuffer; //!< Buffer for raw samples obtained from UDP (I/Q not in a formal I/Q structure)
uint32_t m_sampleRateStream; //!< Current sample rate from the stream meta data
uint32_t m_sampleRate; //!< Current actual sample rate in Hz
uint8_t m_sampleBytes; //!< Current number of bytes per I or Q sample
uint8_t m_sampleBits; //!< Current number of effective bits per sample
bool m_sync; //!< Meta data acquired
bool m_syncLock; //!< Meta data expected (Stream synchronized)
bool m_lz4; //!< Stream is compressed with LZ4
MetaData m_currentMeta; //!< Stored current meta data
CRC64 m_crc64; //!< CRC64 calculator
uint32_t m_nbBlocks; //!< Number of UDP blocks received in the current frame
uint32_t m_bytesInBlock; //!< Number of bytes received in the current UDP block
uint64_t m_dataCRC; //!< CRC64 of the data block
uint32_t m_inCount; //!< Current position of uncompressed input
int m_lz4InCount; //!< Current position in LZ4 input buffer
int m_lz4InSize; //!< Size in bytes of the LZ4 input data
uint8_t *m_lz4InBuffer; //!< Buffer for LZ4 compressed input
uint8_t *m_lz4OutBuffer; //!< Buffer for LZ4 uncompressed output
uint32_t m_frameSize; //!< Size in bytes of one uncompressed frame
float m_bufferLenSec; //!< Raw buffer length in seconds
uint32_t m_nbLz4Decodes;
uint32_t m_nbLz4SuccessfulDecodes;
uint32_t m_nbLz4CRCOK;
uint32_t m_nbLastLz4SuccessfulDecodes;
uint32_t m_nbLastLz4CRCOK;
int32_t m_writeIndex; //!< Current write position in the raw samples buffer
int32_t m_readIndex; //!< Current read position in the raw samples buffer
int m_readSize; //!< Read buffer size
uint8_t *m_readBuffer; //!< Read buffer to hold samples when looping back to beginning of raw buffer
bool m_autoFollowRate; //!< Auto follow stream sample rate else stick with meta data sample rate
bool m_autoCorrBuffer; //!< Auto correct buffer read / write balance (attempt to ...)
bool m_skewTest;
bool m_skewCorrection; //!< Do a skew rate correction at next meta data reception
bool m_resetIndexes; //!< Do a reset indexes at next meta data reception
int64_t m_readCount; //!< Number of bytes read for auto skew compensation
int64_t m_writeCount; //!< Number of bytes written for auto skew compensation
uint32_t m_nbCycles; //!< Number of buffer cycles since start of auto skew compensation byte counting
uint32_t m_nbReads; //!< Number of buffer reads since start of auto R/W balance correction period
int32_t m_balCorrection; //!< R/W balance correction in number of samples
int32_t m_balCorrLimit; //!< Correction absolute value limit in number of samples
};
#endif /* PLUGINS_SAMPLESOURCE_SDRDAEMON_SDRDAEMONBUFFER_H_ */