// Free memory associated with a 'stepcompress' object
public void Dispose()
{
Stepcompress.free(queue);
}
// Find a 'step_move' that covers a series of step times
step_move compress_bisect_add()
{
uint *qlast = queue_next;
if (qlast > queue_pos + 65535)
{
qlast = queue_pos + 65535;
}
points point = minmax_point(queue_pos);
int outer_mininterval = point.minp, outer_maxinterval = point.maxp;
int add = 0, minadd = -0x8000, maxadd = 0x7fff;
int bestinterval = 0, bestcount = 1, bestadd = 1, bestreach = int.MinValue;
int zerointerval = 0, zerocount = 0;
int count, addfactor, nextaddfactor, c;
while (true)
{
// Find longest valid sequence with the given 'add'
points nextpoint;
int nextmininterval = outer_mininterval;
int nextmaxinterval = outer_maxinterval, interval = nextmaxinterval;
int nextcount = 1;
for (; ;)
{
nextcount++;
if (&queue_pos[nextcount - 1] >= qlast)
{
count = nextcount - 1;
return(new step_move((uint)interval, (ushort)count, (short)add));
}
nextpoint = minmax_point(queue_pos + nextcount - 1);
nextaddfactor = nextcount * (nextcount - 1) / 2;
c = add * nextaddfactor;
if (nextmininterval * nextcount < nextpoint.minp - c)
{
nextmininterval = Stepcompress.DIV_ROUND_UP(nextpoint.minp - c, nextcount);
}
if (nextmaxinterval * nextcount > nextpoint.maxp - c)
{
nextmaxinterval = (nextpoint.maxp - c) / nextcount;
}
if (nextmininterval > nextmaxinterval)
{
break;
}
interval = nextmaxinterval;
}
// Check if this is the best sequence found so far
count = nextcount - 1;
addfactor = count * (count - 1) / 2;
int reach = add * addfactor + interval * count;
if (reach > bestreach ||
(reach == bestreach && interval > bestinterval))
{
bestinterval = interval;
bestcount = count;
bestadd = add;
bestreach = reach;
if (add == 0)
{
zerointerval = interval;
zerocount = count;
}
if (count > 0x200)
{
// No 'add' will improve sequence; avoid integer overflow
break;
}
}
// Check if a greater or lesser add could extend the sequence
nextaddfactor = nextcount * (nextcount - 1) / 2;
int nextreach = add * nextaddfactor + interval * nextcount;
if (nextreach < nextpoint.minp)
{
minadd = add + 1;
outer_maxinterval = nextmaxinterval;
}
else
{
maxadd = add - 1;
outer_mininterval = nextmininterval;
}
// The maximum valid deviation between two quadratic sequences
// can be calculated and used to further limit the add range.
if (count > 1)
{
int errdelta = (int)max_error * Stepcompress.QUADRATIC_DEV / (count * count);
if (minadd < add - errdelta)
{
minadd = add - errdelta;
}
if (maxadd > add + errdelta)
{
maxadd = add + errdelta;
}
}
// See if next point would further limit the add range
c = outer_maxinterval * nextcount;
if (minadd * nextaddfactor < nextpoint.minp - c)
{
minadd = Stepcompress.idiv_up(nextpoint.minp - c, nextaddfactor);
}
c = outer_mininterval * nextcount;
if (maxadd * nextaddfactor > nextpoint.maxp - c)
{
maxadd = Stepcompress.idiv_down(nextpoint.maxp - c, nextaddfactor);
}
// Bisect valid add range and try again with new 'add'
if (minadd > maxadd)
{
break;
}
add = maxadd - (maxadd - minadd) / 4;
}
if (zerocount + zerocount / 16 >= bestcount)
{
// Prefer add=0 if it's similar to the best found sequence
return(new step_move((uint)zerointerval, (ushort)zerocount, 0));
}
return(new step_move((uint)bestinterval, (ushort)bestcount, (short)bestadd));
}
// Slow path for queue_append()
public int queue_append_slow(double rel_sc)
{
ulong abs_step_clock = (ulong)(rel_sc + last_step_clock);
if (abs_step_clock >= last_step_clock + Stepcompress.CLOCK_DIFF_MAX)
{
// Avoid integer overflow on steps far in the future
int ret = flush(abs_step_clock - Stepcompress.CLOCK_DIFF_MAX + 1);
if (ret != 0)
{
return(ret);
}
if (abs_step_clock >= last_step_clock + Stepcompress.CLOCK_DIFF_MAX)
{
return(flush_far(abs_step_clock));
}
}
if (queue_next - queue_pos > 65535 + 2000)
{
// No point in keeping more than 64K steps in memory
uint flush = *(queue_next - 65535) - (uint)last_step_clock;
int ret = this.flush(last_step_clock + flush);
if (ret != 0)
{
return(ret);
}
}
if (queue_next >= queue_end)
{
// Make room in the queue
long in_use = queue_next - queue_pos;
if (queue_pos > queue)
{
// Shuffle the internal queue to avoid having to allocate more ram
Stepcompress.memmove(queue, queue_pos, in_use * sizeof(uint));
}
else
{
// Expand the internal queue of step times
long alloc = queue_end - queue;
if (alloc == 0)
{
alloc = Stepcompress.QUEUE_START_SIZE;
}
while (in_use >= alloc)
{
alloc *= 2;
}
queue = (uint *)Stepcompress.realloc(queue, alloc * sizeof(uint));
queue_end = queue + alloc;
}
queue_pos = queue;
queue_next = queue + in_use;
}
*queue_next++ = (uint)abs_step_clock;
return(0);
}