zircon/system/ulib/audio-utils/audio-input.cc - fuchsia - Git at Google

 // Copyright 2017 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <lib/affine/transform.h>
 #include <lib/zx/clock.h>
 #include <zircon/time.h>
 #include <zircon/types.h>

 #include <algorithm>
 #include <cmath>
 #include <limits>
 #include <memory>

 #include <audio-utils/audio-input.h>
 #include <audio-utils/audio-stream.h>
 #include <fbl/algorithm.h>
 #include <fbl/alloc_checker.h>

 namespace audio {
 namespace utils {

 static constexpr zx_duration_t CHUNK_TIME = ZX_MSEC(100);
 static constexpr float MIN_DURATION = 0.100f;
 static constexpr float MAX_DURATION = 86400.0f;

 std::unique_ptr<AudioInput> AudioInput::Create(uint32_t dev_id) {
   fbl::AllocChecker ac;
   std::unique_ptr<AudioInput> res(new (&ac) AudioInput(dev_id));
   if (!ac.check())
     return nullptr;
   return res;
 }

 std::unique_ptr<AudioInput> AudioInput::Create(const char* dev_path) {
   fbl::AllocChecker ac;
   std::unique_ptr<AudioInput> res(new (&ac) AudioInput(dev_path));
   if (!ac.check())
     return nullptr;
   return res;
 }

 zx_status_t AudioInput::Record(AudioSink& sink, Duration duration) {
   auto res = RecordPrepare(sink);
   if (res != ZX_OK)
     return res;
   res = StartRingBuffer();
   if (res != ZX_OK) {
     printf("Failed to start capture (res %d)\n", res);
     return res;
   }
   return RecordToCompletion(sink, duration);
 }

 zx_status_t AudioInput::RecordPrepare(AudioSink& sink) {
   AudioStream::Format fmt = {
       .frame_rate = frame_rate_,
       .channels = static_cast<uint16_t>(channel_cnt_),
       .sample_format = sample_format_,
   };

   zx_status_t res = sink.SetFormat(fmt);
   if (res != ZX_OK) {
     printf("Failed to set sink format (rate %u, chan_count %u, fmt 0x%08x, res %d)\n", frame_rate_,
            channel_cnt_, sample_format_, res);
     return res;
   }

   uint64_t ring_bytes_64 = (zx_duration_mul_int64(CHUNK_TIME, frame_rate_) / ZX_SEC(1)) * frame_sz_;
   if (ring_bytes_64 > std::numeric_limits<uint32_t>::max()) {
     printf("Invalid frame rate %u\n", frame_rate_);
     return res;
   }

   uint32_t ring_bytes = static_cast<uint32_t>(ring_bytes_64);
   uint32_t ring_frames = ring_bytes / frame_sz_;

   res = GetBuffer(ring_frames, 8u);
   if (res != ZX_OK) {
     printf("Failed to establish ring buffer (%u frames, res %d)\n", ring_frames, res);
     return res;
   }

   return res;
 }

 zx_status_t AudioInput::RecordToCompletion(AudioSink& sink, Duration duration) {
   zx_status_t res = ZX_OK;
   long frames_expected = 0;
   int64_t bytes_expected = 0;
   const bool loop = std::holds_alternative<LoopingDoneCallback>(duration);
   if (!loop) {
     std::get<float>(duration) = std::clamp(std::get<float>(duration), MIN_DURATION, MAX_DURATION);
     printf("Recording for %.1f seconds\n", std::get<float>(duration));
     frames_expected = std::lround(frame_rate_ * std::get<float>(duration));
     bytes_expected = frame_sz_ * frames_expected;
   }

   uint32_t rd_ptr = 0;    // Our read ptr for the ring buffer.
   uint32_t wr_ptr = 0;    // Estimated write ptr in the ring buffer.
   uint32_t consumed = 0;  // Total bytes consumed.
   uint32_t produced = 0;  // Estimated total bytes produced.

   // A transformation from time to bytes captured safe to read. We wait until we have received about
   // 4 FIFOs before start reading to make sure we are behind the HW. We start the transformation at
   // -2 FIFOs and wake up after another 2 FIFOs.
   auto mono_to_safe_read_bytes = affine::Transform{static_cast<int64_t>(start_time_),
                                                    -2 * static_cast<int64_t>(fifo_depth_),
                                                    {frame_rate_ * frame_sz_, zx::sec(1).get()}};
   auto next_wake_time = zx::time(mono_to_safe_read_bytes.ApplyInverse(2 * fifo_depth_));

   // Repeat until looping is done or until consumed >= bytes_expected.
   while ((loop && std::get<LoopingDoneCallback>(duration)()) ||
          (!loop && consumed < bytes_expected)) {
     // We specify a floor to avoid not having a reasonable deadline per loop.
     constexpr auto kFloorWait = zx::msec(10);
     auto floor_wake_time = zx::clock::get_monotonic() + kFloorWait;
     if (next_wake_time < floor_wake_time) {
       next_wake_time = floor_wake_time;
     }
     zx::nanosleep(next_wake_time);
     auto safe_read = mono_to_safe_read_bytes.Apply(zx::clock::get_monotonic().get());

     if (loop) {
       consumed = static_cast<uint32_t>(safe_read) - (static_cast<uint32_t>(safe_read) % frame_sz_);
     } else {
       consumed = std::min(safe_read, bytes_expected);
     }
     uint32_t increment = consumed - produced;

     // We want to process about 2 FIFOs worth of samples in each loop.
     next_wake_time = zx::time(mono_to_safe_read_bytes.ApplyInverse(safe_read + 2 * fifo_depth_));

     wr_ptr += increment;
     produced += increment;
     if (wr_ptr > rb_sz_) {
       wr_ptr -= rb_sz_;
     }

     uint32_t todo = wr_ptr + rb_sz_ - rd_ptr;
     if (todo >= rb_sz_) {
       todo -= rb_sz_;
     }

     ZX_DEBUG_ASSERT(todo < rb_sz_);
     ZX_DEBUG_ASSERT(rd_ptr < rb_sz_);

     uint32_t space = rb_sz_ - rd_ptr;
     uint32_t amt = std::min(space, todo);
     auto data = static_cast<const uint8_t*>(rb_virt_) + rd_ptr;

     res = zx_cache_flush(data, amt, ZX_CACHE_FLUSH_DATA | ZX_CACHE_FLUSH_INVALIDATE);
     if (res != ZX_OK) {
       printf("Failed to cache invalidate(res %d).\n", res);
       break;
     }

     res = sink.PutFrames(data, amt);
     if (res != ZX_OK) {
       printf("Failed to record %u bytes (res %d)\n", amt, res);
       break;
     }

     if (amt < todo) {
       amt = todo - amt;
       ZX_DEBUG_ASSERT(amt < rb_sz_);

       res = zx_cache_flush(rb_virt_, amt, ZX_CACHE_FLUSH_DATA | ZX_CACHE_FLUSH_INVALIDATE);
       if (res != ZX_OK) {
         printf("Failed to cache invalidate(res %d) %d\n", res, __LINE__);
         break;
       }

       res = sink.PutFrames(rb_virt_, amt);
       if (res != ZX_OK) {
         printf("Failed to record %u bytes (res %d)\n", amt, res);
         break;
       }

       rd_ptr = amt;
     } else {
       rd_ptr += amt;
       if (rd_ptr >= rb_sz_) {
         ZX_DEBUG_ASSERT(rd_ptr == rb_sz_);
         rd_ptr = 0;
       }
     }
   }

   StopRingBuffer();

   zx_status_t finalize_res = sink.Finalize();
   return (res == ZX_OK) ? finalize_res : res;
 }

 }  // namespace utils
 }  // namespace audio
	// Copyright 2017 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <lib/affine/transform.h>
	#include <lib/zx/clock.h>
	#include <zircon/time.h>
	#include <zircon/types.h>

	#include <algorithm>
	#include <cmath>
	#include <limits>
	#include <memory>

	#include <audio-utils/audio-input.h>
	#include <audio-utils/audio-stream.h>
	#include <fbl/algorithm.h>
	#include <fbl/alloc_checker.h>

	namespace audio {
	namespace utils {

	static constexpr zx_duration_t CHUNK_TIME = ZX_MSEC(100);
	static constexpr float MIN_DURATION = 0.100f;
	static constexpr float MAX_DURATION = 86400.0f;

	std::unique_ptr<AudioInput> AudioInput::Create(uint32_t dev_id) {
	fbl::AllocChecker ac;
	std::unique_ptr<AudioInput> res(new (&ac) AudioInput(dev_id));
	if (!ac.check())
	return nullptr;
	return res;
	}

	std::unique_ptr<AudioInput> AudioInput::Create(const char* dev_path) {
	fbl::AllocChecker ac;
	std::unique_ptr<AudioInput> res(new (&ac) AudioInput(dev_path));
	if (!ac.check())
	return nullptr;
	return res;
	}

	zx_status_t AudioInput::Record(AudioSink& sink, Duration duration) {
	auto res = RecordPrepare(sink);
	if (res != ZX_OK)
	return res;
	res = StartRingBuffer();
	if (res != ZX_OK) {
	printf("Failed to start capture (res %d)\n", res);
	return res;
	}
	return RecordToCompletion(sink, duration);
	}

	zx_status_t AudioInput::RecordPrepare(AudioSink& sink) {
	AudioStream::Format fmt = {
	.frame_rate = frame_rate_,
	.channels = static_cast<uint16_t>(channel_cnt_),
	.sample_format = sample_format_,
	};

	zx_status_t res = sink.SetFormat(fmt);
	if (res != ZX_OK) {
	printf("Failed to set sink format (rate %u, chan_count %u, fmt 0x%08x, res %d)\n", frame_rate_,
	channel_cnt_, sample_format_, res);
	return res;
	}

	uint64_t ring_bytes_64 = (zx_duration_mul_int64(CHUNK_TIME, frame_rate_) / ZX_SEC(1)) * frame_sz_;
	if (ring_bytes_64 > std::numeric_limits<uint32_t>::max()) {
	printf("Invalid frame rate %u\n", frame_rate_);
	return res;
	}

	uint32_t ring_bytes = static_cast<uint32_t>(ring_bytes_64);
	uint32_t ring_frames = ring_bytes / frame_sz_;

	res = GetBuffer(ring_frames, 8u);
	if (res != ZX_OK) {
	printf("Failed to establish ring buffer (%u frames, res %d)\n", ring_frames, res);
	return res;
	}

	return res;
	}

	zx_status_t AudioInput::RecordToCompletion(AudioSink& sink, Duration duration) {
	zx_status_t res = ZX_OK;
	long frames_expected = 0;
	int64_t bytes_expected = 0;
	const bool loop = std::holds_alternative<LoopingDoneCallback>(duration);
	if (!loop) {
	std::get<float>(duration) = std::clamp(std::get<float>(duration), MIN_DURATION, MAX_DURATION);
	printf("Recording for %.1f seconds\n", std::get<float>(duration));
	frames_expected = std::lround(frame_rate_ * std::get<float>(duration));
	bytes_expected = frame_sz_ * frames_expected;
	}

	uint32_t rd_ptr = 0; // Our read ptr for the ring buffer.
	uint32_t wr_ptr = 0; // Estimated write ptr in the ring buffer.
	uint32_t consumed = 0; // Total bytes consumed.
	uint32_t produced = 0; // Estimated total bytes produced.

	// A transformation from time to bytes captured safe to read. We wait until we have received about
	// 4 FIFOs before start reading to make sure we are behind the HW. We start the transformation at
	// -2 FIFOs and wake up after another 2 FIFOs.
	auto mono_to_safe_read_bytes = affine::Transform{static_cast<int64_t>(start_time_),
	-2 * static_cast<int64_t>(fifo_depth_),
	{frame_rate_ * frame_sz_, zx::sec(1).get()}};
	auto next_wake_time = zx::time(mono_to_safe_read_bytes.ApplyInverse(2 * fifo_depth_));

	// Repeat until looping is done or until consumed >= bytes_expected.
	while ((loop && std::get<LoopingDoneCallback>(duration)()) \|\|
	(!loop && consumed < bytes_expected)) {
	// We specify a floor to avoid not having a reasonable deadline per loop.
	constexpr auto kFloorWait = zx::msec(10);
	auto floor_wake_time = zx::clock::get_monotonic() + kFloorWait;
	if (next_wake_time < floor_wake_time) {
	next_wake_time = floor_wake_time;
	}
	zx::nanosleep(next_wake_time);
	auto safe_read = mono_to_safe_read_bytes.Apply(zx::clock::get_monotonic().get());

	if (loop) {
	consumed = static_cast<uint32_t>(safe_read) - (static_cast<uint32_t>(safe_read) % frame_sz_);
	} else {
	consumed = std::min(safe_read, bytes_expected);
	}
	uint32_t increment = consumed - produced;

	// We want to process about 2 FIFOs worth of samples in each loop.
	next_wake_time = zx::time(mono_to_safe_read_bytes.ApplyInverse(safe_read + 2 * fifo_depth_));

	wr_ptr += increment;
	produced += increment;
	if (wr_ptr > rb_sz_) {
	wr_ptr -= rb_sz_;
	}

	uint32_t todo = wr_ptr + rb_sz_ - rd_ptr;
	if (todo >= rb_sz_) {
	todo -= rb_sz_;
	}

	ZX_DEBUG_ASSERT(todo < rb_sz_);
	ZX_DEBUG_ASSERT(rd_ptr < rb_sz_);

	uint32_t space = rb_sz_ - rd_ptr;
	uint32_t amt = std::min(space, todo);
	auto data = static_cast<const uint8_t*>(rb_virt_) + rd_ptr;

	res = zx_cache_flush(data, amt, ZX_CACHE_FLUSH_DATA \| ZX_CACHE_FLUSH_INVALIDATE);
	if (res != ZX_OK) {
	printf("Failed to cache invalidate(res %d).\n", res);
	break;
	}

	res = sink.PutFrames(data, amt);
	if (res != ZX_OK) {
	printf("Failed to record %u bytes (res %d)\n", amt, res);
	break;
	}

	if (amt < todo) {
	amt = todo - amt;
	ZX_DEBUG_ASSERT(amt < rb_sz_);

	res = zx_cache_flush(rb_virt_, amt, ZX_CACHE_FLUSH_DATA \| ZX_CACHE_FLUSH_INVALIDATE);
	if (res != ZX_OK) {
	printf("Failed to cache invalidate(res %d) %d\n", res, __LINE__);
	break;
	}

	res = sink.PutFrames(rb_virt_, amt);
	if (res != ZX_OK) {
	printf("Failed to record %u bytes (res %d)\n", amt, res);
	break;
	}

	rd_ptr = amt;
	} else {
	rd_ptr += amt;
	if (rd_ptr >= rb_sz_) {
	ZX_DEBUG_ASSERT(rd_ptr == rb_sz_);
	rd_ptr = 0;
	}
	}
	}

	StopRingBuffer();

	zx_status_t finalize_res = sink.Finalize();
	return (res == ZX_OK) ? finalize_res : res;
	}

	} // namespace utils
	} // namespace audio