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/*
Copyright (C) 2005, 2206, 2007, 2008, 2009, 2010, 2011 Her Majesty
the Queen in Right of Canada (Communications Research Center Canada)
Copyright (C) 2017
Matthias P. Braendli, matthias.braendli@mpb.li
http://opendigitalradio.org
*/
/*
This file is part of ODR-DabMod.
ODR-DabMod 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.
ODR-DabMod 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 ODR-DabMod. If not, see <http://www.gnu.org/licenses/>.
*/
#include "GuardIntervalInserter.h"
#include "PcDebug.h"
#include <string.h>
#include <stdexcept>
#include <complex>
#include <mutex>
typedef std::complex<float> complexf;
GuardIntervalInserter::GuardIntervalInserter(
size_t nbSymbols,
size_t spacing,
size_t nullSize,
size_t symSize,
size_t& windowOverlap) :
ModCodec(),
RemoteControllable("guardinterval"),
d_nbSymbols(nbSymbols),
d_spacing(spacing),
d_nullSize(nullSize),
d_symSize(symSize),
d_windowOverlap(windowOverlap)
{
if (d_nullSize == 0) {
throw std::logic_error("NULL symbol must be present");
}
RC_ADD_PARAMETER(windowlen, "Window length for OFDM windowng [0 to disable]");
/* We use a raised-cosine window for the OFDM windowing.
* Each symbol is extended on both sides by d_windowOverlap samples.
*
*
* Sym n |####################|
* Sym n+1 |####################|
*
* We now extend the symbols by d_windowOverlap (one dash)
*
* Sym n extended -|####################|-
* Sym n+1 extended -|####################|-
*
* The windows are raised-cosine:
* ____________________
* Sym n window / \
* ... ____/ \___________ ...
*
* Sym n+1 window ____________________
* / \
* ... ________________/ \__ ...
*
* The window length is 2*d_windowOverlap.
*/
update_window(windowOverlap);
PDEBUG("GuardIntervalInserter::GuardIntervalInserter"
"(%zu, %zu, %zu, %zu, %zu) @ %p\n",
nbSymbols, spacing, nullSize, symSize, windowOverlap, this);
}
void GuardIntervalInserter::update_window(size_t new_window_overlap)
{
std::lock_guard<std::mutex> lock(d_windowMutex);
d_windowOverlap = new_window_overlap;
// d_window only contains the rising window edge.
d_window.resize(2*d_windowOverlap);
for (size_t i = 0; i < 2*d_windowOverlap; i++) {
d_window[i] = (float)(0.5 * (1.0 - cos(M_PI * i / (2*d_windowOverlap - 1))));
}
}
int GuardIntervalInserter::process(Buffer* const dataIn, Buffer* dataOut)
{
PDEBUG("GuardIntervalInserter::process(dataIn: %p, dataOut: %p)\n",
dataIn, dataOut);
std::lock_guard<std::mutex> lock(d_windowMutex);
// Every symbol overlaps over a length of d_windowOverlap with
// the previous symbol, and with the next symbol. First symbol
// receives no prefix window, because we don't remember the
// last symbol from the previous TF (yet). Last symbol also
// receives no suffix window, for the same reason.
// Overall output buffer length must stay independent of the windowing.
dataOut->setLength((d_nullSize + (d_nbSymbols * d_symSize)) * sizeof(complexf));
const complexf* in = reinterpret_cast<const complexf*>(dataIn->getData());
complexf* out = reinterpret_cast<complexf*>(dataOut->getData());
size_t sizeIn = dataIn->getLength() / sizeof(complexf);
const size_t num_symbols = d_nbSymbols + 1;
if (sizeIn != num_symbols * d_spacing)
{
PDEBUG("Nb symbols: %zu\n", d_nbSymbols);
PDEBUG("Spacing: %zu\n", d_spacing);
PDEBUG("Null size: %zu\n", d_nullSize);
PDEBUG("Sym size: %zu\n", d_symSize);
PDEBUG("\n%zu != %zu\n", sizeIn, (d_nbSymbols + 1) * d_spacing);
throw std::runtime_error(
"GuardIntervalInserter::process input size not valid!");
}
// TODO remember the end of the last TF so that we can do some
// windowing too.
if (d_windowOverlap) {
{
// Handle Null symbol separately because it is longer
const size_t prefixlength = d_nullSize - d_spacing;
// end = spacing
memcpy(out, &in[d_spacing - prefixlength],
prefixlength * sizeof(complexf));
memcpy(&out[prefixlength], in, (d_spacing - d_windowOverlap) * sizeof(complexf));
// The remaining part of the symbol must have half of the window applied,
// sloping down from 1 to 0.5
for (size_t i = 0; i < d_windowOverlap; i++) {
const size_t out_ix = prefixlength + d_spacing - d_windowOverlap + i;
const size_t in_ix = d_spacing - d_windowOverlap + i;
out[out_ix] = in[in_ix] * d_window[2*d_windowOverlap - (i+1)];
}
// Suffix is taken from the beginning of the symbol, and sees the other
// half of the window applied.
for (size_t i = 0; i < d_windowOverlap; i++) {
const size_t out_ix = prefixlength + d_spacing + i;
out[out_ix] = in[i] * d_window[d_windowOverlap - (i+1)];
}
in += d_spacing;
out += d_nullSize;
// out is now pointing to the proper end of symbol. There are
// d_windowOverlap samples ahead that were already written.
}
// Data symbols
for (size_t sym_ix = 0; sym_ix < d_nbSymbols; sym_ix++) {
/* _ix variables are indices into in[], _ox variables are
* indices for out[] */
const ssize_t start_rise_ox = -d_windowOverlap;
const size_t start_rise_ix = 2 * d_spacing - d_symSize - d_windowOverlap;
/*
const size_t start_real_symbol_ox = 0;
const size_t start_real_symbol_ix = 2 * d_spacing - d_symSize;
*/
const ssize_t end_rise_ox = d_windowOverlap;
const size_t end_rise_ix = 2 * d_spacing - d_symSize + d_windowOverlap;
const ssize_t end_cyclic_prefix_ox = d_symSize - d_spacing;
/* end_cyclic_prefix_ix = end of symbol
const size_t begin_fall_ox = d_symSize - d_windowOverlap;
const size_t begin_fall_ix = d_spacing - d_windowOverlap;
const size_t end_real_symbol_ox = d_symSize;
end_real_symbol_ix = end of symbol
const size_t end_fall_ox = d_symSize + d_windowOverlap;
const size_t end_fall_ix = d_spacing + d_windowOverlap;
*/
ssize_t ox = start_rise_ox;
size_t ix = start_rise_ix;
for (size_t i = 0; ix < end_rise_ix; i++) {
out[ox] += in[ix] * d_window.at(i);
ix++;
ox++;
}
assert(ox == end_rise_ox);
const size_t remaining_prefix_length = end_cyclic_prefix_ox - end_rise_ox;
memcpy( &out[ox], &in[ix],
remaining_prefix_length * sizeof(complexf));
ox += remaining_prefix_length;
assert(ox == end_cyclic_prefix_ox);
ix = 0;
const bool last_symbol = (sym_ix + 1 >= d_nbSymbols);
if (last_symbol) {
// No windowing at all at end
memcpy(&out[ox], &in[ix], d_spacing * sizeof(complexf));
ox += d_spacing;
}
else {
// Copy the middle part of the symbol, d_windowOverlap samples
// short of the end.
memcpy( &out[ox],
&in[ix],
(d_spacing - d_windowOverlap) * sizeof(complexf));
ox += d_spacing - d_windowOverlap;
ix += d_spacing - d_windowOverlap;
assert(ox == (ssize_t)(d_symSize - d_windowOverlap));
// Apply window from 1 to 0.5 for the end of the symbol
for (size_t i = 0; ox < (ssize_t)d_symSize; i++) {
out[ox] = in[ix] * d_window[2*d_windowOverlap - (i+1)];
ox++;
ix++;
}
assert(ix == d_spacing);
ix = 0;
// Cyclic suffix, with window from 0.5 to 0
for (size_t i = 0; ox < (ssize_t)(d_symSize + d_windowOverlap); i++) {
out[ox] = in[ix] * d_window[d_windowOverlap - (i+1)];
ox++;
ix++;
}
assert(ix == d_windowOverlap);
}
out += d_symSize;
in += d_spacing;
// out is now pointing to the proper end of symbol. There are
// d_windowOverlap samples ahead that were already written.
}
}
else {
// Handle Null symbol separately because it is longer
// end - (nullSize - spacing) = 2 * spacing - nullSize
memcpy(out, &in[2 * d_spacing - d_nullSize],
(d_nullSize - d_spacing) * sizeof(complexf));
memcpy(&out[d_nullSize - d_spacing], in, d_spacing * sizeof(complexf));
in += d_spacing;
out += d_nullSize;
// Data symbols
for (size_t i = 0; i < d_nbSymbols; ++i) {
// end - (symSize - spacing) = 2 * spacing - symSize
memcpy(out, &in[2 * d_spacing - d_symSize],
(d_symSize - d_spacing) * sizeof(complexf));
memcpy(&out[d_symSize - d_spacing], in, d_spacing * sizeof(complexf));
in += d_spacing;
out += d_symSize;
}
}
return sizeIn;
}
void GuardIntervalInserter::set_parameter(
const std::string& parameter,
const std::string& value)
{
using namespace std;
stringstream ss(value);
ss.exceptions ( stringstream::failbit | stringstream::badbit );
if (parameter == "windowlen") {
size_t new_window_overlap = 0;
ss >> new_window_overlap;
update_window(new_window_overlap);
}
else {
stringstream ss_err;
ss_err << "Parameter '" << parameter <<
"' is not exported by controllable " << get_rc_name();
throw ParameterError(ss_err.str());
}
}
const std::string GuardIntervalInserter::get_parameter(const std::string& parameter) const
{
using namespace std;
stringstream ss;
if (parameter == "windowlen") {
ss << d_windowOverlap;
}
else {
ss << "Parameter '" << parameter <<
"' is not exported by controllable " << get_rc_name();
throw ParameterError(ss.str());
}
return ss.str();
}
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