[pulseview.git] / pv / data / logicsegment.cpp

/*
 * This file is part of the PulseView project.
 *
 * Copyright (C) 2012 Joel Holdsworth <joel@airwebreathe.org.uk>
 *
 * 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; either version 2 of the License, or
 * (at your option) any later version.
 *
 * 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 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/>.
 */

#include "config.h" // For HAVE_UNALIGNED_LITTLE_ENDIAN_ACCESS

#include <extdef.h>

#include <cassert>
#include <cmath>
#include <cstdlib>
#include <cstring>
#include <cstdint>

#include "logic.hpp"
#include "logicsegment.hpp"

#include <libsigrokcxx/libsigrokcxx.hpp>

using std::lock_guard;
using std::recursive_mutex;
using std::max;
using std::min;
using std::shared_ptr;
using std::vector;

using sigrok::Logic;

namespace pv {
namespace data {

const int LogicSegment::MipMapScalePower = 4;
const int LogicSegment::MipMapScaleFactor = 1 << MipMapScalePower;
const float LogicSegment::LogMipMapScaleFactor = logf(MipMapScaleFactor);
const uint64_t LogicSegment::MipMapDataUnit = 64 * 1024; // bytes

LogicSegment::LogicSegment(pv::data::Logic& owner, uint32_t segment_id,
	unsigned int unit_size,	uint64_t samplerate) :
	Segment(segment_id, samplerate, unit_size),
	owner_(owner),
	last_append_sample_(0)
{
	memset(mip_map_, 0, sizeof(mip_map_));
}

LogicSegment::~LogicSegment()
{
	lock_guard<recursive_mutex> lock(mutex_);
	for (MipMapLevel &l : mip_map_)
		free(l.data);
}

inline uint64_t LogicSegment::unpack_sample(const uint8_t *ptr) const
{
#ifdef HAVE_UNALIGNED_LITTLE_ENDIAN_ACCESS
	return *(uint64_t*)ptr;
#else
	uint64_t value = 0;
	switch (unit_size_) {
	default:
		value |= ((uint64_t)ptr[7]) << 56;
		/* FALLTHRU */
	case 7:
		value |= ((uint64_t)ptr[6]) << 48;
		/* FALLTHRU */
	case 6:
		value |= ((uint64_t)ptr[5]) << 40;
		/* FALLTHRU */
	case 5:
		value |= ((uint64_t)ptr[4]) << 32;
		/* FALLTHRU */
	case 4:
		value |= ((uint32_t)ptr[3]) << 24;
		/* FALLTHRU */
	case 3:
		value |= ((uint32_t)ptr[2]) << 16;
		/* FALLTHRU */
	case 2:
		value |= ptr[1] << 8;
		/* FALLTHRU */
	case 1:
		value |= ptr[0];
		/* FALLTHRU */
	case 0:
		break;
	}
	return value;
#endif
}

inline void LogicSegment::pack_sample(uint8_t *ptr, uint64_t value)
{
#ifdef HAVE_UNALIGNED_LITTLE_ENDIAN_ACCESS
	*(uint64_t*)ptr = value;
#else
	switch (unit_size_) {
	default:
		ptr[7] = value >> 56;
		/* FALLTHRU */
	case 7:
		ptr[6] = value >> 48;
		/* FALLTHRU */
	case 6:
		ptr[5] = value >> 40;
		/* FALLTHRU */
	case 5:
		ptr[4] = value >> 32;
		/* FALLTHRU */
	case 4:
		ptr[3] = value >> 24;
		/* FALLTHRU */
	case 3:
		ptr[2] = value >> 16;
		/* FALLTHRU */
	case 2:
		ptr[1] = value >> 8;
		/* FALLTHRU */
	case 1:
		ptr[0] = value;
		/* FALLTHRU */
	case 0:
		break;
	}
#endif
}

void LogicSegment::append_payload(shared_ptr<sigrok::Logic> logic)
{
	assert(unit_size_ == logic->unit_size());
	assert((logic->data_length() % unit_size_) == 0);

	append_payload(logic->data_pointer(), logic->data_length());
}

void LogicSegment::append_payload(void *data, uint64_t data_size)
{
	assert((data_size % unit_size_) == 0);

	lock_guard<recursive_mutex> lock(mutex_);

	const uint64_t prev_sample_count = sample_count_;
	const uint64_t sample_count = data_size / unit_size_;

	append_samples(data, sample_count);

	// Generate the first mip-map from the data
	append_payload_to_mipmap();

	if (sample_count > 1)
		owner_.notify_samples_added(this, prev_sample_count + 1,
			prev_sample_count + 1 + sample_count);
	else
		owner_.notify_samples_added(this, prev_sample_count + 1,
			prev_sample_count + 1);
}

void LogicSegment::get_samples(int64_t start_sample,
	int64_t end_sample,	uint8_t* dest) const
{
	assert(start_sample >= 0);
	assert(start_sample <= (int64_t)sample_count_);
	assert(end_sample >= 0);
	assert(end_sample <= (int64_t)sample_count_);
	assert(start_sample <= end_sample);
	assert(dest != nullptr);

	lock_guard<recursive_mutex> lock(mutex_);

	get_raw_samples(start_sample, (end_sample - start_sample), dest);
}

SegmentLogicDataIterator* LogicSegment::begin_sample_iteration(uint64_t start)
{
	return (SegmentLogicDataIterator*)begin_raw_sample_iteration(start);
}

void LogicSegment::continue_sample_iteration(SegmentLogicDataIterator* it, uint64_t increase)
{
	Segment::continue_raw_sample_iteration((SegmentRawDataIterator*)it, increase);
}

void LogicSegment::end_sample_iteration(SegmentLogicDataIterator* it)
{
	Segment::end_raw_sample_iteration((SegmentRawDataIterator*)it);
}

void LogicSegment::reallocate_mipmap_level(MipMapLevel &m)
{
	lock_guard<recursive_mutex> lock(mutex_);

	const uint64_t new_data_length = ((m.length + MipMapDataUnit - 1) /
		MipMapDataUnit) * MipMapDataUnit;

	if (new_data_length > m.data_length) {
		m.data_length = new_data_length;

		// Padding is added to allow for the uint64_t write word
		m.data = realloc(m.data, new_data_length * unit_size_ +
			sizeof(uint64_t));
	}
}

void LogicSegment::append_payload_to_mipmap()
{
	MipMapLevel &m0 = mip_map_[0];
	uint64_t prev_length;
	uint8_t *dest_ptr;
	SegmentRawDataIterator* it;
	uint64_t accumulator;
	unsigned int diff_counter;

	// Expand the data buffer to fit the new samples
	prev_length = m0.length;
	m0.length = sample_count_ / MipMapScaleFactor;

	// Break off if there are no new samples to compute
	if (m0.length == prev_length)
		return;

	reallocate_mipmap_level(m0);

	dest_ptr = (uint8_t*)m0.data + prev_length * unit_size_;

	// Iterate through the samples to populate the first level mipmap
	const uint64_t start_sample = prev_length * MipMapScaleFactor;
	const uint64_t end_sample = m0.length * MipMapScaleFactor;

	it = begin_raw_sample_iteration(start_sample);
	for (uint64_t i = start_sample; i < end_sample;) {
		// Accumulate transitions which have occurred in this sample
		accumulator = 0;
		diff_counter = MipMapScaleFactor;
		while (diff_counter-- > 0) {
			const uint64_t sample = unpack_sample(it->value);
			accumulator |= last_append_sample_ ^ sample;
			last_append_sample_ = sample;
			continue_raw_sample_iteration(it, 1);
			i++;
		}

		pack_sample(dest_ptr, accumulator);
		dest_ptr += unit_size_;
	}
	end_raw_sample_iteration(it);

	// Compute higher level mipmaps
	for (unsigned int level = 1; level < ScaleStepCount; level++) {
		MipMapLevel &m = mip_map_[level];
		const MipMapLevel &ml = mip_map_[level - 1];

		// Expand the data buffer to fit the new samples
		prev_length = m.length;
		m.length = ml.length / MipMapScaleFactor;

		// Break off if there are no more samples to be computed
		if (m.length == prev_length)
			break;

		reallocate_mipmap_level(m);

		// Subsample the lower level
		const uint8_t* src_ptr = (uint8_t*)ml.data +
			unit_size_ * prev_length * MipMapScaleFactor;
		const uint8_t *const end_dest_ptr =
			(uint8_t*)m.data + unit_size_ * m.length;

		for (dest_ptr = (uint8_t*)m.data +
				unit_size_ * prev_length;
				dest_ptr < end_dest_ptr;
				dest_ptr += unit_size_) {
			accumulator = 0;
			diff_counter = MipMapScaleFactor;
			while (diff_counter-- > 0) {
				accumulator |= unpack_sample(src_ptr);
				src_ptr += unit_size_;
			}

			pack_sample(dest_ptr, accumulator);
		}
	}
}

uint64_t LogicSegment::get_unpacked_sample(uint64_t index) const
{
	assert(index < sample_count_);

	assert(unit_size_ <= 8);  // 8 * 8 = 64 channels
	uint8_t data[8];

	get_raw_samples(index, 1, data);

	return unpack_sample(data);
}

void LogicSegment::get_subsampled_edges(
	vector<EdgePair> &edges,
	uint64_t start, uint64_t end,
	float min_length, int sig_index)
{
	uint64_t index = start;
	unsigned int level;
	bool last_sample;
	bool fast_forward;

	assert(start <= end);
	assert(min_length > 0);
	assert(sig_index >= 0);
	assert(sig_index < 64);

	lock_guard<recursive_mutex> lock(mutex_);

	// Make sure we only process as many samples as we have
	if (end > get_sample_count())
		end = get_sample_count();

	const uint64_t block_length = (uint64_t)max(min_length, 1.0f);
	const unsigned int min_level = max((int)floorf(logf(min_length) /
		LogMipMapScaleFactor) - 1, 0);
	const uint64_t sig_mask = 1ULL << sig_index;

	// Store the initial state
	last_sample = (get_unpacked_sample(start) & sig_mask) != 0;
	edges.emplace_back(index++, last_sample);

	while (index + block_length <= end) {
		//----- Continue to search -----//
		level = min_level;

		// We cannot fast-forward if there is no mip-map data at
		// the minimum level.
		fast_forward = (mip_map_[level].data != nullptr);

		if (min_length < MipMapScaleFactor) {
			// Search individual samples up to the beginning of
			// the next first level mip map block
			const uint64_t final_index = min(end, pow2_ceil(index, MipMapScalePower));

			for (; index < final_index &&
					(index & ~((uint64_t)(~0) << MipMapScalePower)) != 0;
					index++) {

				const bool sample = (get_unpacked_sample(index) & sig_mask) != 0;

				// If there was a change we cannot fast forward
				if (sample != last_sample) {
					fast_forward = false;
					break;
				}
			}
		} else {
			// If resolution is less than a mip map block,
			// round up to the beginning of the mip-map block
			// for this level of detail
			const int min_level_scale_power = (level + 1) * MipMapScalePower;
			index = pow2_ceil(index, min_level_scale_power);
			if (index >= end)
				break;

			// We can fast forward only if there was no change
			const bool sample = (get_unpacked_sample(index) & sig_mask) != 0;
			if (last_sample != sample)
				fast_forward = false;
		}

		if (fast_forward) {

			// Fast forward: This involves zooming out to higher
			// levels of the mip map searching for changes, then
			// zooming in on them to find the point where the edge
			// begins.

			// Slide right and zoom out at the beginnings of mip-map
			// blocks until we encounter a change
			while (true) {
				const int level_scale_power = (level + 1) * MipMapScalePower;
				const uint64_t offset = index >> level_scale_power;

				// Check if we reached the last block at this
				// level, or if there was a change in this block
				if (offset >= mip_map_[level].length ||
					(get_subsample(level, offset) &	sig_mask))
					break;

				if ((offset & ~((uint64_t)(~0) << MipMapScalePower)) == 0) {
					// If we are now at the beginning of a
					// higher level mip-map block ascend one
					// level
					if ((level + 1 >= ScaleStepCount) || (!mip_map_[level + 1].data))
						break;

					level++;
				} else {
					// Slide right to the beginning of the
					// next mip map block
					index = pow2_ceil(index + 1, level_scale_power);
				}
			}

			// Zoom in, and slide right until we encounter a change,
			// and repeat until we reach min_level
			while (true) {
				assert(mip_map_[level].data);

				const int level_scale_power = (level + 1) * MipMapScalePower;
				const uint64_t offset = index >> level_scale_power;

				// Check if we reached the last block at this
				// level, or if there was a change in this block
				if (offset >= mip_map_[level].length ||
						(get_subsample(level, offset) & sig_mask)) {
					// Zoom in unless we reached the minimum
					// zoom
					if (level == min_level)
						break;

					level--;
				} else {
					// Slide right to the beginning of the
					// next mip map block
					index = pow2_ceil(index + 1, level_scale_power);
				}
			}

			// If individual samples within the limit of resolution,
			// do a linear search for the next transition within the
			// block
			if (min_length < MipMapScaleFactor) {
				for (; index < end; index++) {
					const bool sample = (get_unpacked_sample(index) & sig_mask) != 0;
					if (sample != last_sample)
						break;
				}
			}
		}

		//----- Store the edge -----//

		// Take the last sample of the quanization block
		const int64_t final_index = index + block_length;
		if (index + block_length > end)
			break;

		// Store the final state
		const bool final_sample = (get_unpacked_sample(final_index - 1) & sig_mask) != 0;
		edges.emplace_back(index, final_sample);

		index = final_index;
		last_sample = final_sample;
	}

	// Add the final state
	const bool end_sample = get_unpacked_sample(end) & sig_mask;
	if (last_sample != end_sample)
		edges.emplace_back(end, end_sample);
	edges.emplace_back(end + 1, end_sample);
}

uint64_t LogicSegment::get_subsample(int level, uint64_t offset) const
{
	assert(level >= 0);
	assert(mip_map_[level].data);
	return unpack_sample((uint8_t*)mip_map_[level].data +
		unit_size_ * offset);
}

uint64_t LogicSegment::pow2_ceil(uint64_t x, unsigned int power)
{
	const uint64_t p = UINT64_C(1) << power;
	return (x + p - 1) / p * p;
}

} // namespace data
} // namespace pv
Commit	Line	Data
	1	/*
	2	* This file is part of the PulseView project.
	3	*
	4	* Copyright (C) 2012 Joel Holdsworth <joel@airwebreathe.org.uk>
	5	*
	6	* This program is free software; you can redistribute it and/or modify
	7	* it under the terms of the GNU General Public License as published by
	8	* the Free Software Foundation; either version 2 of the License, or
	9	* (at your option) any later version.
	10	*
	11	* This program is distributed in the hope that it will be useful,
	12	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	* GNU General Public License for more details.
	15	*
	16	* You should have received a copy of the GNU General Public License
	17	* along with this program; if not, see <http://www.gnu.org/licenses/>.
	18	*/
	19
	20	#include "config.h" // For HAVE_UNALIGNED_LITTLE_ENDIAN_ACCESS
	21
	22	#include <extdef.h>
	23
	24	#include <cassert>
	25	#include <cmath>
	26	#include <cstdlib>
	27	#include <cstring>
	28	#include <cstdint>
	29
	30	#include "logic.hpp"
	31	#include "logicsegment.hpp"
	32
	33	#include <libsigrokcxx/libsigrokcxx.hpp>
	34
	35	using std::lock_guard;
	36	using std::recursive_mutex;
	37	using std::max;
	38	using std::min;
	39	using std::shared_ptr;
	40	using std::vector;
	41
	42	using sigrok::Logic;
	43
	44	namespace pv {
	45	namespace data {
	46
	47	const int LogicSegment::MipMapScalePower = 4;
	48	const int LogicSegment::MipMapScaleFactor = 1 << MipMapScalePower;
	49	const float LogicSegment::LogMipMapScaleFactor = logf(MipMapScaleFactor);
	50	const uint64_t LogicSegment::MipMapDataUnit = 64 * 1024; // bytes
	51
	52	LogicSegment::LogicSegment(pv::data::Logic& owner, uint32_t segment_id,
	53	unsigned int unit_size, uint64_t samplerate) :
	54	Segment(segment_id, samplerate, unit_size),
	55	owner_(owner),
	56	last_append_sample_(0)
	57	{
	58	memset(mip_map_, 0, sizeof(mip_map_));
	59	}
	60
	61	LogicSegment::~LogicSegment()
	62	{
	63	lock_guard<recursive_mutex> lock(mutex_);
	64	for (MipMapLevel &l : mip_map_)
	65	free(l.data);
	66	}
	67
	68	inline uint64_t LogicSegment::unpack_sample(const uint8_t *ptr) const
	69	{
	70	#ifdef HAVE_UNALIGNED_LITTLE_ENDIAN_ACCESS
	71	return (uint64_t)ptr;
	72	#else
	73	uint64_t value = 0;
	74	switch (unit_size_) {
	75	default:
	76	value \|= ((uint64_t)ptr[7]) << 56;
	77	/* FALLTHRU */
	78	case 7:
	79	value \|= ((uint64_t)ptr[6]) << 48;
	80	/* FALLTHRU */
	81	case 6:
	82	value \|= ((uint64_t)ptr[5]) << 40;
	83	/* FALLTHRU */
	84	case 5:
	85	value \|= ((uint64_t)ptr[4]) << 32;
	86	/* FALLTHRU */
	87	case 4:
	88	value \|= ((uint32_t)ptr[3]) << 24;
	89	/* FALLTHRU */
	90	case 3:
	91	value \|= ((uint32_t)ptr[2]) << 16;
	92	/* FALLTHRU */
	93	case 2:
	94	value \|= ptr[1] << 8;
	95	/* FALLTHRU */
	96	case 1:
	97	value \|= ptr[0];
	98	/* FALLTHRU */
	99	case 0:
	100	break;
	101	}
	102	return value;
	103	#endif
	104	}
	105
	106	inline void LogicSegment::pack_sample(uint8_t *ptr, uint64_t value)
	107	{
	108	#ifdef HAVE_UNALIGNED_LITTLE_ENDIAN_ACCESS
	109	(uint64_t)ptr = value;
	110	#else
	111	switch (unit_size_) {
	112	default:
	113	ptr[7] = value >> 56;
	114	/* FALLTHRU */
	115	case 7:
	116	ptr[6] = value >> 48;
	117	/* FALLTHRU */
	118	case 6:
	119	ptr[5] = value >> 40;
	120	/* FALLTHRU */
	121	case 5:
	122	ptr[4] = value >> 32;
	123	/* FALLTHRU */
	124	case 4:
	125	ptr[3] = value >> 24;
	126	/* FALLTHRU */
	127	case 3:
	128	ptr[2] = value >> 16;
	129	/* FALLTHRU */
	130	case 2:
	131	ptr[1] = value >> 8;
	132	/* FALLTHRU */
	133	case 1:
	134	ptr[0] = value;
	135	/* FALLTHRU */
	136	case 0:
	137	break;
	138	}
	139	#endif
	140	}
	141
	142	void LogicSegment::append_payload(shared_ptr<sigrok::Logic> logic)
	143	{
	144	assert(unit_size_ == logic->unit_size());
	145	assert((logic->data_length() % unit_size_) == 0);
	146
	147	append_payload(logic->data_pointer(), logic->data_length());
	148	}
	149
	150	void LogicSegment::append_payload(void *data, uint64_t data_size)
	151	{
	152	assert((data_size % unit_size_) == 0);
	153
	154	lock_guard<recursive_mutex> lock(mutex_);
	155
	156	const uint64_t prev_sample_count = sample_count_;
	157	const uint64_t sample_count = data_size / unit_size_;
	158
	159	append_samples(data, sample_count);
	160
	161	// Generate the first mip-map from the data
	162	append_payload_to_mipmap();
	163
	164	if (sample_count > 1)
	165	owner_.notify_samples_added(this, prev_sample_count + 1,
	166	prev_sample_count + 1 + sample_count);
	167	else
	168	owner_.notify_samples_added(this, prev_sample_count + 1,
	169	prev_sample_count + 1);
	170	}
	171
	172	void LogicSegment::get_samples(int64_t start_sample,
	173	int64_t end_sample, uint8_t* dest) const
	174	{
	175	assert(start_sample >= 0);
	176	assert(start_sample <= (int64_t)sample_count_);
	177	assert(end_sample >= 0);
	178	assert(end_sample <= (int64_t)sample_count_);
	179	assert(start_sample <= end_sample);
	180	assert(dest != nullptr);
	181
	182	lock_guard<recursive_mutex> lock(mutex_);
	183
	184	get_raw_samples(start_sample, (end_sample - start_sample), dest);
	185	}
	186
	187	SegmentLogicDataIterator* LogicSegment::begin_sample_iteration(uint64_t start)
	188	{
	189	return (SegmentLogicDataIterator*)begin_raw_sample_iteration(start);
	190	}
	191
	192	void LogicSegment::continue_sample_iteration(SegmentLogicDataIterator* it, uint64_t increase)
	193	{
	194	Segment::continue_raw_sample_iteration((SegmentRawDataIterator*)it, increase);
	195	}
	196
	197	void LogicSegment::end_sample_iteration(SegmentLogicDataIterator* it)
	198	{
	199	Segment::end_raw_sample_iteration((SegmentRawDataIterator*)it);
	200	}
	201
	202	void LogicSegment::reallocate_mipmap_level(MipMapLevel &m)
	203	{
	204	lock_guard<recursive_mutex> lock(mutex_);
	205
	206	const uint64_t new_data_length = ((m.length + MipMapDataUnit - 1) /
	207	MipMapDataUnit) * MipMapDataUnit;
	208
	209	if (new_data_length > m.data_length) {
	210	m.data_length = new_data_length;
	211
	212	// Padding is added to allow for the uint64_t write word
	213	m.data = realloc(m.data, new_data_length * unit_size_ +
	214	sizeof(uint64_t));
	215	}
	216	}
	217
	218	void LogicSegment::append_payload_to_mipmap()
	219	{
	220	MipMapLevel &m0 = mip_map_[0];
	221	uint64_t prev_length;
	222	uint8_t *dest_ptr;
	223	SegmentRawDataIterator* it;
	224	uint64_t accumulator;
	225	unsigned int diff_counter;
	226
	227	// Expand the data buffer to fit the new samples
	228	prev_length = m0.length;
	229	m0.length = sample_count_ / MipMapScaleFactor;
	230
	231	// Break off if there are no new samples to compute
	232	if (m0.length == prev_length)
	233	return;
	234
	235	reallocate_mipmap_level(m0);
	236
	237	dest_ptr = (uint8_t)m0.data + prev_length unit_size_;
	238
	239	// Iterate through the samples to populate the first level mipmap
	240	const uint64_t start_sample = prev_length * MipMapScaleFactor;
	241	const uint64_t end_sample = m0.length * MipMapScaleFactor;
	242
	243	it = begin_raw_sample_iteration(start_sample);
	244	for (uint64_t i = start_sample; i < end_sample;) {
	245	// Accumulate transitions which have occurred in this sample
	246	accumulator = 0;
	247	diff_counter = MipMapScaleFactor;
	248	while (diff_counter-- > 0) {
	249	const uint64_t sample = unpack_sample(it->value);
	250	accumulator \|= last_append_sample_ ^ sample;
	251	last_append_sample_ = sample;
	252	continue_raw_sample_iteration(it, 1);
	253	i++;
	254	}
	255
	256	pack_sample(dest_ptr, accumulator);
	257	dest_ptr += unit_size_;
	258	}
	259	end_raw_sample_iteration(it);
	260
	261	// Compute higher level mipmaps
	262	for (unsigned int level = 1; level < ScaleStepCount; level++) {
	263	MipMapLevel &m = mip_map_[level];
	264	const MipMapLevel &ml = mip_map_[level - 1];
	265
	266	// Expand the data buffer to fit the new samples
	267	prev_length = m.length;
	268	m.length = ml.length / MipMapScaleFactor;
	269
	270	// Break off if there are no more samples to be computed
	271	if (m.length == prev_length)
	272	break;
	273
	274	reallocate_mipmap_level(m);
	275
	276	// Subsample the lower level
	277	const uint8_t* src_ptr = (uint8_t*)ml.data +
	278	unit_size_ * prev_length * MipMapScaleFactor;
	279	const uint8_t *const end_dest_ptr =
	280	(uint8_t)m.data + unit_size_ m.length;
	281
	282	for (dest_ptr = (uint8_t*)m.data +
	283	unit_size_ * prev_length;
	284	dest_ptr < end_dest_ptr;
	285	dest_ptr += unit_size_) {
	286	accumulator = 0;
	287	diff_counter = MipMapScaleFactor;
	288	while (diff_counter-- > 0) {
	289	accumulator \|= unpack_sample(src_ptr);
	290	src_ptr += unit_size_;
	291	}
	292
	293	pack_sample(dest_ptr, accumulator);
	294	}
	295	}
	296	}
	297
	298	uint64_t LogicSegment::get_unpacked_sample(uint64_t index) const
	299	{
	300	assert(index < sample_count_);
	301
	302	assert(unit_size_ <= 8); // 8 * 8 = 64 channels
	303	uint8_t data[8];
	304
	305	get_raw_samples(index, 1, data);
	306
	307	return unpack_sample(data);
	308	}
	309
	310	void LogicSegment::get_subsampled_edges(
	311	vector<EdgePair> &edges,
	312	uint64_t start, uint64_t end,
	313	float min_length, int sig_index)
	314	{
	315	uint64_t index = start;
	316	unsigned int level;
	317	bool last_sample;
	318	bool fast_forward;
	319
	320	assert(start <= end);
	321	assert(min_length > 0);
	322	assert(sig_index >= 0);
	323	assert(sig_index < 64);
	324
	325	lock_guard<recursive_mutex> lock(mutex_);
	326
	327	// Make sure we only process as many samples as we have
	328	if (end > get_sample_count())
	329	end = get_sample_count();
	330
	331	const uint64_t block_length = (uint64_t)max(min_length, 1.0f);
	332	const unsigned int min_level = max((int)floorf(logf(min_length) /
	333	LogMipMapScaleFactor) - 1, 0);
	334	const uint64_t sig_mask = 1ULL << sig_index;
	335
	336	// Store the initial state
	337	last_sample = (get_unpacked_sample(start) & sig_mask) != 0;
	338	edges.emplace_back(index++, last_sample);
	339
	340	while (index + block_length <= end) {
	341	//----- Continue to search -----//
	342	level = min_level;
	343
	344	// We cannot fast-forward if there is no mip-map data at
	345	// the minimum level.
	346	fast_forward = (mip_map_[level].data != nullptr);
	347
	348	if (min_length < MipMapScaleFactor) {
	349	// Search individual samples up to the beginning of
	350	// the next first level mip map block
	351	const uint64_t final_index = min(end, pow2_ceil(index, MipMapScalePower));
	352
	353	for (; index < final_index &&
	354	(index & ~((uint64_t)(~0) << MipMapScalePower)) != 0;
	355	index++) {
	356
	357	const bool sample = (get_unpacked_sample(index) & sig_mask) != 0;
	358
	359	// If there was a change we cannot fast forward
	360	if (sample != last_sample) {
	361	fast_forward = false;
	362	break;
	363	}
	364	}
	365	} else {
	366	// If resolution is less than a mip map block,
	367	// round up to the beginning of the mip-map block
	368	// for this level of detail
	369	const int min_level_scale_power = (level + 1) * MipMapScalePower;
	370	index = pow2_ceil(index, min_level_scale_power);
	371	if (index >= end)
	372	break;
	373
	374	// We can fast forward only if there was no change
	375	const bool sample = (get_unpacked_sample(index) & sig_mask) != 0;
	376	if (last_sample != sample)
	377	fast_forward = false;
	378	}
	379
	380	if (fast_forward) {
	381
	382	// Fast forward: This involves zooming out to higher
	383	// levels of the mip map searching for changes, then
	384	// zooming in on them to find the point where the edge
	385	// begins.
	386
	387	// Slide right and zoom out at the beginnings of mip-map
	388	// blocks until we encounter a change
	389	while (true) {
	390	const int level_scale_power = (level + 1) * MipMapScalePower;
	391	const uint64_t offset = index >> level_scale_power;
	392
	393	// Check if we reached the last block at this
	394	// level, or if there was a change in this block
	395	if (offset >= mip_map_[level].length \|\|
	396	(get_subsample(level, offset) & sig_mask))
	397	break;
	398
	399	if ((offset & ~((uint64_t)(~0) << MipMapScalePower)) == 0) {
	400	// If we are now at the beginning of a
	401	// higher level mip-map block ascend one
	402	// level
	403	if ((level + 1 >= ScaleStepCount) \|\| (!mip_map_[level + 1].data))
	404	break;
	405
	406	level++;
	407	} else {
	408	// Slide right to the beginning of the
	409	// next mip map block
	410	index = pow2_ceil(index + 1, level_scale_power);
	411	}
	412	}
	413
	414	// Zoom in, and slide right until we encounter a change,
	415	// and repeat until we reach min_level
	416	while (true) {
	417	assert(mip_map_[level].data);
	418
	419	const int level_scale_power = (level + 1) * MipMapScalePower;
	420	const uint64_t offset = index >> level_scale_power;
	421
	422	// Check if we reached the last block at this
	423	// level, or if there was a change in this block
	424	if (offset >= mip_map_[level].length \|\|
	425	(get_subsample(level, offset) & sig_mask)) {
	426	// Zoom in unless we reached the minimum
	427	// zoom
	428	if (level == min_level)
	429	break;
	430
	431	level--;
	432	} else {
	433	// Slide right to the beginning of the
	434	// next mip map block
	435	index = pow2_ceil(index + 1, level_scale_power);
	436	}
	437	}
	438
	439	// If individual samples within the limit of resolution,
	440	// do a linear search for the next transition within the
	441	// block
	442	if (min_length < MipMapScaleFactor) {
	443	for (; index < end; index++) {
	444	const bool sample = (get_unpacked_sample(index) & sig_mask) != 0;
	445	if (sample != last_sample)
	446	break;
	447	}
	448	}
	449	}
	450
	451	//----- Store the edge -----//
	452
	453	// Take the last sample of the quanization block
	454	const int64_t final_index = index + block_length;
	455	if (index + block_length > end)
	456	break;
	457
	458	// Store the final state
	459	const bool final_sample = (get_unpacked_sample(final_index - 1) & sig_mask) != 0;
	460	edges.emplace_back(index, final_sample);
	461
	462	index = final_index;
	463	last_sample = final_sample;
	464	}
	465
	466	// Add the final state
	467	const bool end_sample = get_unpacked_sample(end) & sig_mask;
	468	if (last_sample != end_sample)
	469	edges.emplace_back(end, end_sample);
	470	edges.emplace_back(end + 1, end_sample);
	471	}
	472
	473	uint64_t LogicSegment::get_subsample(int level, uint64_t offset) const
	474	{
	475	assert(level >= 0);
	476	assert(mip_map_[level].data);
	477	return unpack_sample((uint8_t*)mip_map_[level].data +
	478	unit_size_ * offset);
	479	}
	480
	481	uint64_t LogicSegment::pow2_ceil(uint64_t x, unsigned int power)
	482	{
	483	const uint64_t p = UINT64_C(1) << power;
	484	return (x + p - 1) / p * p;
	485	}
	486
	487	} // namespace data
	488	} // namespace pv