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/* -*- c++ -*- */
/*
* Copyright 2004,2009,2010 Free Software Foundation, Inc.
*
* This file is part of GNU Radio
*
* GNU Radio 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, or (at your option)
* any later version.
*
* GNU Radio 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 GNU Radio; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <gr_buffer.h>
#include <gr_vmcircbuf.h>
#include <gr_math.h>
#include <stdexcept>
#include <iostream>
#include <assert.h>
#include <algorithm>
static long s_buffer_count = 0; // counts for debugging storage mgmt
static long s_buffer_reader_count = 0;
// ----------------------------------------------------------------------------
// Notes on storage management
//
// Pretty much all the fundamental classes are now using the
// shared_ptr stuff for automatic reference counting. To ensure that
// no mistakes are made, we make the constructors for classes private,
// and then provide a free factory function that returns a smart
// pointer to the desired class.
//
// gr_buffer and gr_buffer_reader are no exceptions. However, they
// both want pointers to each other, and unless we do something, we'll
// never delete any of them because of the circular structure.
// They'll always have a reference count of at least one. We could
// use boost::weak_ptr's from gr_buffer to gr_buffer_reader but that
// introduces it's own problems. (gr_buffer_reader's destructor needs
// to call gr_buffer::drop_reader, but has no easy way to get a
// shared_ptr to itself.)
//
// Instead, we solve this problem by having gr_buffer hold a raw
// pointer to gr_buffer_reader in its d_reader vector.
// gr_buffer_reader's destructor calls gr_buffer::drop_reader, so
// we're never left with an dangling pointer. gr_buffer_reader still
// has a shared_ptr to the buffer ensuring that the buffer doesn't go
// away under it. However, when the reference count of a
// gr_buffer_reader goes to zero, we can successfully reclaim it.
// ----------------------------------------------------------------------------
/*
* Compute the minimum number of buffer items that work (i.e.,
* address space wrap-around works). To work is to satisfy this
* contraint for integer buffer_size and k:
*
* type_size * nitems == k * page_size
*/
static long
minimum_buffer_items (long type_size, long page_size)
{
return page_size / gr_gcd (type_size, page_size);
}
gr_buffer::gr_buffer (int nitems, size_t sizeof_item, gr_block_sptr link)
: d_base (0), d_bufsize (0), d_vmcircbuf (0),
d_sizeof_item (sizeof_item), d_link(link),
d_write_index (0), d_abs_write_offset(0), d_done (false)
{
if (!allocate_buffer (nitems, sizeof_item))
throw std::bad_alloc ();
s_buffer_count++;
}
gr_buffer_sptr
gr_make_buffer (int nitems, size_t sizeof_item, gr_block_sptr link)
{
return gr_buffer_sptr (new gr_buffer (nitems, sizeof_item, link));
}
gr_buffer::~gr_buffer ()
{
delete d_vmcircbuf;
assert (d_readers.size() == 0);
s_buffer_count--;
}
/*!
* sets d_vmcircbuf, d_base, d_bufsize.
* returns true iff successful.
*/
bool
gr_buffer::allocate_buffer (int nitems, size_t sizeof_item)
{
int orig_nitems = nitems;
// Any buffersize we come up with must be a multiple of min_nitems.
int granularity = gr_vmcircbuf_sysconfig::granularity ();
int min_nitems = minimum_buffer_items (sizeof_item, granularity);
// Round-up nitems to a multiple of min_nitems.
if (nitems % min_nitems != 0)
nitems = ((nitems / min_nitems) + 1) * min_nitems;
// If we rounded-up a whole bunch, give the user a heads up.
// This only happens if sizeof_item is not a power of two.
if (nitems > 2 * orig_nitems && nitems * (int) sizeof_item > granularity){
std::cerr << "gr_buffer::allocate_buffer: warning: tried to allocate\n"
<< " " << orig_nitems << " items of size "
<< sizeof_item << ". Due to alignment requirements\n"
<< " " << nitems << " were allocated. If this isn't OK, consider padding\n"
<< " your structure to a power-of-two bytes.\n"
<< " On this platform, our allocation granularity is " << granularity << " bytes.\n";
}
d_bufsize = nitems;
d_vmcircbuf = gr_vmcircbuf_sysconfig::make (d_bufsize * d_sizeof_item);
if (d_vmcircbuf == 0){
std::cerr << "gr_buffer::allocate_buffer: failed to allocate buffer of size "
<< d_bufsize * d_sizeof_item / 1024 << " KB\n";
return false;
}
d_base = (char *) d_vmcircbuf->pointer_to_first_copy ();
return true;
}
int
gr_buffer::space_available ()
{
if (d_readers.empty ())
return d_bufsize - 1; // See comment below
else {
// Find out the maximum amount of data available to our readers
int most_data = d_readers[0]->items_available ();
uint64_t min_items_read = d_readers[0]->nitems_read();
for (size_t i = 1; i < d_readers.size (); i++) {
most_data = std::max (most_data, d_readers[i]->items_available ());
min_items_read = std::min(min_items_read, d_readers[i]->nitems_read());
}
for (size_t i = 0; i < d_readers.size (); i++) {
d_readers[i]->prune_tags(min_items_read);
}
// The -1 ensures that the case d_write_index == d_read_index is
// unambiguous. It indicates that there is no data for the reader
return d_bufsize - most_data - 1;
}
}
void *
gr_buffer::write_pointer ()
{
return &d_base[d_write_index * d_sizeof_item];
}
void
gr_buffer::update_write_pointer (int nitems)
{
gruel::scoped_lock guard(*mutex());
d_write_index = index_add (d_write_index, nitems);
d_abs_write_offset += nitems;
}
void
gr_buffer::set_done (bool done)
{
gruel::scoped_lock guard(*mutex());
d_done = done;
}
gr_buffer_reader_sptr
gr_buffer_add_reader (gr_buffer_sptr buf, int nzero_preload, gr_block_sptr link)
{
if (nzero_preload < 0)
throw std::invalid_argument("gr_buffer_add_reader: nzero_preload must be >= 0");
gr_buffer_reader_sptr r (new gr_buffer_reader (buf,
buf->index_sub(buf->d_write_index,
nzero_preload),
link));
buf->d_readers.push_back (r.get ());
return r;
}
void
gr_buffer::drop_reader (gr_buffer_reader *reader)
{
// isn't C++ beautiful... GAG!
std::vector<gr_buffer_reader *>::iterator result =
std::find (d_readers.begin (), d_readers.end (), reader);
if (result == d_readers.end ())
throw std::invalid_argument ("gr_buffer::drop_reader"); // we didn't find it...
d_readers.erase (result);
}
void
gr_buffer::add_item_tag(const pmt::pmt_t &tag)
{
gruel::scoped_lock guard(*mutex());
d_item_tags.push_back(tag);
}
long
gr_buffer_ncurrently_allocated ()
{
return s_buffer_count;
}
// ----------------------------------------------------------------------------
gr_buffer_reader::gr_buffer_reader(gr_buffer_sptr buffer, unsigned int read_index,
gr_block_sptr link)
: d_buffer(buffer), d_read_index(read_index), d_abs_read_offset(0), d_link(link)
{
s_buffer_reader_count++;
}
gr_buffer_reader::~gr_buffer_reader ()
{
d_buffer->drop_reader(this);
s_buffer_reader_count--;
}
int
gr_buffer_reader::items_available () const
{
return d_buffer->index_sub (d_buffer->d_write_index, d_read_index);
}
const void *
gr_buffer_reader::read_pointer ()
{
return &d_buffer->d_base[d_read_index * d_buffer->d_sizeof_item];
}
void
gr_buffer_reader::update_read_pointer (int nitems)
{
gruel::scoped_lock guard(*mutex());
d_read_index = d_buffer->index_add (d_read_index, nitems);
d_abs_read_offset += nitems;
}
void
gr_buffer_reader::get_tags_in_range(std::vector<pmt::pmt_t> &v,
uint64_t abs_start,
uint64_t abs_end)
{
gruel::scoped_lock guard(*mutex());
v.resize(0);
std::deque<pmt::pmt_t>::iterator itr = d_buffer->get_tags_begin();
uint64_t item_time;
while(itr != d_buffer->get_tags_end()) {
item_time = pmt::pmt_to_uint64(pmt::pmt_tuple_ref(*itr, 0));
if((item_time >= abs_start) && (item_time <= abs_end)) {
v.push_back(*itr);
}
itr++;
}
}
void
gr_buffer_reader::prune_tags(uint64_t max_time)
{
int n = 0;
uint64_t item_time;
std::deque<pmt::pmt_t>::iterator itr = d_buffer->get_tags_begin();
while(itr != d_buffer->get_tags_end()) {
item_time = pmt::pmt_to_uint64(pmt::pmt_tuple_ref(*itr, 0));
if(item_time < max_time) {
d_buffer->tags_pop_front();
n++;
}
//else
// break;
itr++;
}
}
long
gr_buffer_reader_ncurrently_allocated ()
{
return s_buffer_reader_count;
}
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