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sdrangel/plugins/channelrx/demoddatv/leansdr/generic.h
2018-03-04 01:47:51 +01:00

408 lines
10 KiB
C++

#ifndef LEANSDR_GENERIC_H
#define LEANSDR_GENERIC_H
#include <sys/types.h>
#include <unistd.h>
#include "leansdr/math.h"
namespace leansdr
{
//////////////////////////////////////////////////////////////////////
// Simple blocks
//////////////////////////////////////////////////////////////////////
// [file_reader] reads raw data from a file descriptor into a [pipebuf].
// If the file descriptor is seekable, data can be looped.
template<typename T>
struct file_reader: runnable
{
file_reader(scheduler *sch, int _fdin, pipebuf<T> &_out) :
runnable(sch, _out.name), loop(false), fdin(_fdin), out(_out)
{
}
void run()
{
size_t size = out.writable() * sizeof(T);
if (!size)
return;
again: ssize_t nr = read(fdin, out.wr(), size);
if (nr < 0)
{
fatal("leansdr::file_reader::run: read");
return;
}
if (!nr)
{
if (!loop)
return;
if (sch->debug)
fprintf(stderr, "leansdr::file_reader::run: %s looping\n", name);
off_t res = lseek(fdin, 0, SEEK_SET);
if (res == (off_t) -1)
{
fatal("leansdr::file_reader::run: lseek");
return;
}
goto again;
}
// Always stop at element boundary (may block)
size_t partial = nr % sizeof(T);
size_t remain = partial ? sizeof(T) - partial : 0;
while (remain)
{
if (sch->debug)
fprintf(stderr, "+");
ssize_t nr2 = read(fdin, (char*) out.wr() + nr, remain);
if (nr2 <= 0)
{
fatal("leansdr::file_reader::run: partial read");
return;
}
nr += nr2;
remain -= nr2;
}
out.written(nr / sizeof(T));
}
bool loop;
private:
int fdin;
pipewriter<T> out;
};
// [file_writer] writes raw data from a [pipebuf] to a file descriptor.
template<typename T>
struct file_writer: runnable
{
file_writer(scheduler *sch, pipebuf<T> &_in, int _fdout) :
runnable(sch, _in.name), in(_in), fdout(_fdout)
{
}
void run()
{
int size = in.readable() * sizeof(T);
if (!size)
return;
int nw = write(fdout, in.rd(), size);
if (!nw)
{
fatal("leansdr::file_writer::run: pipe");
return;
}
if (nw < 0)
{
fatal("leansdr::file_writer::run: write");
return;
}
if (nw % sizeof(T))
{
fatal("leansdr::file_writer::run:partial write");
return;
}
in.read(nw / sizeof(T));
}
private:
pipereader<T> in;
int fdout;
};
// [file_printer] writes data from a [pipebuf] to a file descriptor,
// with printf-style formatting and optional scaling.
template<typename T>
struct file_printer: runnable
{
file_printer(scheduler *sch, const char *_format, pipebuf<T> &_in, int _fdout, int _decimation = 1) :
runnable(sch, _in.name), scale(1), decimation(_decimation), in(_in), format(_format), fdout(_fdout), phase(0)
{
}
void run()
{
int n = in.readable();
T *pin = in.rd(), *pend = pin + n;
for (; pin < pend; ++pin)
{
if (++phase >= decimation)
{
phase -= decimation;
char buf[256];
int len = snprintf(buf, sizeof(buf), format, (*pin) * scale);
if (len < 0)
{
fatal("leansdr::file_printer::run: obsolete glibc");
return;
}
int nw = write(fdout, buf, len);
if (nw != len)
{
fatal("leansdr::file_printer::run: partial write");
return;
}
}
}
in.read(n);
}
T scale;
int decimation;
private:
pipereader<T> in;
const char *format;
int fdout;
int phase;
};
// [file_carrayprinter] writes all data available from a [pipebuf]
// to a file descriptor on a single line.
// Special case for complex.
template<typename T>
struct file_carrayprinter: runnable
{
file_carrayprinter(scheduler *sch, const char *_head, const char *_format, const char *_sep, const char *_tail, pipebuf<complex<T> > &_in, int _fdout) :
runnable(sch, _in.name), scale(1), fixed_size(0), in(_in), head(_head), format(_format), sep(_sep), tail(_tail), fout(fdopen(_fdout, "w"))
{
}
void run()
{
int n, nmin = fixed_size ? fixed_size : 1;
while ((n = in.readable()) >= nmin)
{
if (fixed_size)
n = fixed_size;
if (fout)
{
fprintf(fout, head, n);
complex<T> *pin = in.rd();
for (int i = 0; i < n; ++i)
{
if (i)
fprintf(fout, "%s", sep);
fprintf(fout, format, pin[i].re * scale, pin[i].im * scale);
}
fprintf(fout, "%s", tail);
}
fflush(fout);
in.read(n);
}
}
T scale;
int fixed_size; // Number of elements per batch, or 0.
private:
pipereader<complex<T> > in;
const char *head, *format, *sep, *tail;
FILE *fout;
};
template<typename T, int N>
struct file_vectorprinter: runnable
{
file_vectorprinter(scheduler *sch, const char *_head, const char *_format, const char *_sep, const char *_tail, pipebuf<T[N]> &_in, int _fdout) :
runnable(sch, _in.name), scale(1), in(_in), head(_head), format(_format), sep(_sep), tail(_tail)
{
fout = fdopen(_fdout, "w");
if (!fout)
{
fatal("leansdr::file_vectorprinter::file_vectorprinter: fdopen");
}
}
void run()
{
while (in.readable() >= 1)
{
fprintf(fout, head, N);
T (*pin)[N] = in.rd();
for (int i = 0; i < N; ++i)
{
if (i)
fprintf(fout, "%s", sep);
fprintf(fout, format, (*pin)[i] * scale);
}
fprintf(fout, "%s", tail);
in.read(1);
}
fflush(fout);
}
T scale;
private:
pipereader<T[N]> in;
const char *head, *format, *sep, *tail;
FILE *fout;
};
// [itemcounter] writes the number of input items to the output [pipebuf].
// [Tout] must be a numeric type.
template<typename Tin, typename Tout>
struct itemcounter: runnable
{
itemcounter(scheduler *sch, pipebuf<Tin> &_in, pipebuf<Tout> &_out) :
runnable(sch, "itemcounter"), in(_in), out(_out)
{
}
void run()
{
if (out.writable() < 1)
return;
unsigned long count = in.readable();
if (!count)
return;
out.write(count);
in.read(count);
}
private:
pipereader<Tin> in;
pipewriter<Tout> out;
};
// [decimator] forwards 1 in N sample.
template<typename T>
struct decimator: runnable
{
unsigned int d;
decimator(scheduler *sch, int _d, pipebuf<T> &_in, pipebuf<T> &_out) :
runnable(sch, "decimator"), d(_d), in(_in), out(_out)
{
}
void run()
{
unsigned long count = min(in.readable() / d, out.writable());
T *pin = in.rd(), *pend = pin + count * d, *pout = out.wr();
for (; pin < pend; pin += d, ++pout)
*pout = *pin;
in.read(count * d);
out.written(count);
}
private:
pipereader<T> in;
pipewriter<T> out;
};
// [rate_estimator] accumulates counts of two quantities
// and periodically outputs their ratio.
template<typename T>
struct rate_estimator: runnable
{
int sample_size;
rate_estimator(scheduler *sch, pipebuf<int> &_num, pipebuf<int> &_den, pipebuf<float> &_rate) :
runnable(sch, "rate_estimator"), sample_size(10000), num(_num), den(_den), rate(_rate), acc_num(0), acc_den(0)
{
}
void run()
{
if (rate.writable() < 1)
return;
int count = min(num.readable(), den.readable());
int *pnum = num.rd(), *pden = den.rd();
for (int n = count; n--; ++pnum, ++pden)
{
acc_num += *pnum;
acc_den += *pden;
}
num.read(count);
den.read(count);
if (acc_den >= sample_size)
{
rate.write((float) acc_num / acc_den);
acc_num = acc_den = 0;
}
}
private:
pipereader<int> num, den;
pipewriter<float> rate;
T acc_num, acc_den;
};
// SERIALIZER
template<typename Tin, typename Tout>
struct serializer: runnable
{
serializer(scheduler *sch __attribute__((unused)), pipebuf<Tin> &_in, pipebuf<Tout> &_out) :
nin(max((size_t) 1, sizeof(Tin) / sizeof(Tout))), nout(max((size_t) 1, sizeof(Tout) / sizeof(Tin))), in(_in), out(_out, nout)
{
if (nin * sizeof(Tin) != nout * sizeof(Tout))
{
fail("serializer::serializer", "incompatible sizes");
return;
}
}
void run()
{
while (in.readable() >= nin && out.writable() >= nout)
{
memcpy(out.wr(), in.rd(), nout * sizeof(Tout));
in.read(nin);
out.written(nout);
}
}
private:
int nin, nout;
pipereader<Tin> in;
pipewriter<Tout> out;
};
// serializer
// [buffer_reader] reads from a user-supplied buffer.
template<typename T>
struct buffer_reader: runnable
{
buffer_reader(scheduler *sch, T *_data, int _count, pipebuf<T> &_out) :
runnable(sch, "buffer_reader"), data(_data), count(_count), out(_out), pos(0)
{
}
void run()
{
int n = min(out.writable(), (unsigned long) (count - pos));
memcpy(out.wr(), &data[pos], n * sizeof(T));
pos += n;
out.written(n);
}
private:
T *data;
int count;
pipewriter<T> out;
int pos;
};
// buffer_reader
// [buffer_writer] writes to a user-supplied buffer.
template<typename T>
struct buffer_writer: runnable
{
buffer_writer(scheduler *sch, pipebuf<T> &_in, T *_data, int _count) :
runnable(sch, "buffer_reader"), in(_in), data(_data), count(_count), pos(0)
{
}
void run()
{
int n = min(in.readable(), (unsigned long) (count - pos));
memcpy(&data[pos], in.rd(), n * sizeof(T));
in.read(n);
pos += n;
}
private:
pipereader<T> in;
T *data;
int count;
int pos;
};
// buffer_writer
}// namespace
#endif // LEANSDR_GENERIC_H