src/devices/lib/amlogic/aml-tdm-out-audio.cc - fuchsia - Git at Google

 // Copyright 2018 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 <limits>
 #include <memory>
 #include <utility>

 #include <ddk/debug.h>
 #include <fbl/alloc_checker.h>
 #include <soc/aml-common/aml-tdm-audio.h>

 // static
 std::unique_ptr<AmlTdmDevice> AmlTdmOutDevice::Create(ddk::MmioBuffer mmio, ee_audio_mclk_src_t src,
                                                       aml_tdm_out_t tdm, aml_frddr_t frddr,
                                                       aml_tdm_mclk_t mclk,
                                                       metadata::AmlVersion version) {
   // FRDDR A has 256 64-bit lines in the FIFO, B and C have 128.
   uint32_t fifo_depth = 128 * 8;  // in bytes.
   if (frddr == FRDDR_A) {
     fifo_depth = 256 * 8;
   }

   fbl::AllocChecker ac;
   auto dev = std::unique_ptr<AmlTdmDevice>(
       new (&ac) AmlTdmOutDevice(std::move(mmio), src, tdm, frddr, mclk, fifo_depth, version));
   if (!ac.check()) {
     return nullptr;
   }

   return dev;
 }

 void AmlTdmOutDevice::Initialize() {
   // Enable the audio domain clocks used by this instance.
   AudioClkEna((EE_AUDIO_CLK_GATE_TDMOUTA << tdm_ch_) | (EE_AUDIO_CLK_GATE_FRDDRA << frddr_ch_) |
               EE_AUDIO_CLK_GATE_ARB);

   InitMclk();

   // Set the sclk and lrclk sources to the chosen mclk channel
   zx_off_t ptr = EE_AUDIO_CLK_TDMOUT_A_CTL + tdm_ch_ * sizeof(uint32_t);

   // We set the Frame Sync sclk invert bit that shifts the delta between FS and DATA, and
   // allows FS of width 1.
   constexpr uint32_t sclk_ws_inv = 1;
   mmio_.Write32((0x03 << 30) | (sclk_ws_inv << 28) | (mclk_ch_ << 24) | (mclk_ch_ << 20), ptr);

   // Enable DDR ARB, and enable this ddr channels bit.
   mmio_.SetBits32((1 << 31) | (1 << (4 + frddr_ch_)), EE_AUDIO_ARB_CTRL);

   // Disable the FRDDR Channel
   // Only use one buffer
   // Interrupts off
   // ack delay = 0
   // set destination tdm block and enable that selection
   switch (version_) {
     case metadata::AmlVersion::kS905D2G:
       mmio_.Write32(tdm_ch_ | (1 << 3), GetFrddrOffset(FRDDR_CTRL0_OFFS));
       break;
     case metadata::AmlVersion::kS905D3G:
       mmio_.Write32(tdm_ch_ | (1 << 4), GetFrddrOffset(FRDDR_CTRL2_OFFS_D3G));
       break;
   }
   // use entire fifo, start transfer request when fifo is at 1/2 full
   // set the magic force end bit(12) to cause fetch from start
   //    -this only happens when the bit is set from 0->1 (edge)
   // fifo depth needs to be configured in terms of 64-bit lines.
   mmio_.Write32((1 << 12) | (((fifo_depth_ / 8) - 1) << 24) | ((((fifo_depth_ / 8) / 2) - 1) << 16),
                 GetFrddrOffset(FRDDR_CTRL1_OFFS));

   // Value to be inserted in a slot if it is muted
   mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE_VAL_OFFS));
   // Value to be inserted in a slot if it is masked
   mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MASK_VAL_OFFS));

   mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE0_OFFS));  // Disable lane 0 muting.
   mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE1_OFFS));  // Disable lane 1 muting.
   mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE2_OFFS));  // Disable lane 2 muting.
   mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE3_OFFS));  // Disable lane 3 muting.

   // Datasheets state that PAD_CTRL1 controls sclk and lrclk source selection (which mclk),
   // it does this per pad (0, 1, 2).  These pads are tied to the TDM channel in use
   // (this is not specified in the datasheets but confirmed empirically) such that TDM_OUT_A
   // corresponds to pad 0, TDM_OUT_B to pad 1, and TDM_OUT_C to pad 2.
   uint32_t pad1 = {};
   switch (version_) {
     case metadata::AmlVersion::kS905D2G:
       pad1 = EE_AUDIO_MST_PAD_CTRL1;
       break;
     case metadata::AmlVersion::kS905D3G:
       pad1 = EE_AUDIO_MST_PAD_CTRL1_D3G;
       break;
   }
   switch (tdm_ch_) {
     case TDM_OUT_A:
       mmio_.Write32((mclk_ch_ << 16) | (mclk_ch_ << 0), pad1);
       break;
     case TDM_OUT_B:
       mmio_.Write32((mclk_ch_ << 20) | (mclk_ch_ << 4), pad1);
       break;
     case TDM_OUT_C:
       mmio_.Write32((mclk_ch_ << 24) | (mclk_ch_ << 8), pad1);
       break;
   }
 }

 uint32_t AmlTdmOutDevice::GetRingPosition() {
   return mmio_.Read32(GetFrddrOffset(FRDDR_STATUS2_OFFS)) -
          mmio_.Read32(GetFrddrOffset(FRDDR_START_ADDR_OFFS));
 }

 zx_status_t AmlTdmOutDevice::SetBuffer(zx_paddr_t buf, size_t len) {
   // Ensure ring buffer resides in lower memory (dma pointers are 32-bit)
   //    and len is at least 8 (size of each dma operation)
   if (((buf + len - 1) > std::numeric_limits<uint32_t>::max()) || (len < 8)) {
     return ZX_ERR_INVALID_ARGS;
   }

   // Write32 the start and end pointers.  Each fetch is 64-bits, so end pointer
   //    is pointer to the last 64-bit fetch (inclusive)
   mmio_.Write32(static_cast<uint32_t>(buf), GetFrddrOffset(FRDDR_START_ADDR_OFFS));
   mmio_.Write32(static_cast<uint32_t>(buf + len - 8), GetFrddrOffset(FRDDR_FINISH_ADDR_OFFS));
   return ZX_OK;
 }

 /*
     bit_offset - bit position in frame where first slot will appear
                     (position 0 is concurrent with frame sync)
     num_slots - number of slots per frame minus one
     bits_per_slot - width of each slot minus one
     bits_per_sample - number of bits in sample minus one
     mix_mask - lanes to mix L+R.
 */
 void AmlTdmOutDevice::ConfigTdmSlot(uint8_t bit_offset, uint8_t num_slots, uint8_t bits_per_slot,
                                     uint8_t bits_per_sample, uint8_t mix_mask, bool i2s_mode) {
   switch (version_) {
     case metadata::AmlVersion::kS905D2G: {
       uint32_t reg0 = bits_per_slot | (num_slots << 5) | (bit_offset << 15) | (mix_mask << 20);
       mmio_.Write32(reg0, GetTdmOffset(TDMOUT_CTRL0_OFFS));
     } break;
     case metadata::AmlVersion::kS905D3G: {
       uint32_t reg0 =
           bits_per_slot | (num_slots << 5) | (bit_offset << 15) | (1 << 31);  // Bit 31 to enable.
       mmio_.Write32(reg0, GetTdmOffset(TDMOUT_CTRL0_OFFS));
       uint32_t reg2 = (mix_mask << 0);
       mmio_.Write32(reg2, GetTdmOffset(TDMOUT_CTRL2_OFFS_D3G));
     } break;
   }

   uint32_t reg = (bits_per_sample << 8) | (frddr_ch_ << 24);
   if (bits_per_sample <= 8) {
     // 8 bit sample, left justify in frame, split 64-bit dma fetch into 8 samples
     reg |= (0 << 4);
   } else if (bits_per_sample <= 16) {
     // 16 bit sample, left justify in frame, split 64-bit dma fetch into 4 samples
     reg |= (2 << 4);
   } else {
     // 32/24 bit sample, left justify in slot, split 64-bit dma fetch into 2 samples
     reg |= (4 << 4);
   }
   mmio_.Write32(reg, GetTdmOffset(TDMOUT_CTRL1_OFFS));
 }

 zx_status_t AmlTdmOutDevice::ConfigTdmLane(size_t lane, uint32_t enable_mask, uint32_t mute_mask) {
   switch (lane) {
     case 0:
       mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK0_OFFS));
       mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE0_OFFS));
       break;
     case 1:
       mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK1_OFFS));
       mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE1_OFFS));
       break;
     case 2:
       mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK2_OFFS));
       mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE2_OFFS));
       break;
     case 3:
       mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK3_OFFS));
       mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE3_OFFS));
       break;
     default:
       return ZX_ERR_INVALID_ARGS;
   }
   return ZX_OK;
 }

 void AmlTdmOutDevice::ConfigTdmSwaps(uint32_t swaps) {
   mmio_.Write32(swaps, GetTdmOffset(TDMOUT_SWAP_OFFS));
 }

 // Stops the tdm from clocking data out of fifo onto bus
 void AmlTdmOutDevice::TdmOutDisable() {
   mmio_.ClearBits32(1 << 31, GetTdmOffset(TDMOUT_CTRL0_OFFS));
 }
 // Enables the tdm to clock data out of fifo onto bus
 void AmlTdmOutDevice::TdmOutEnable() { mmio_.SetBits32(1 << 31, GetTdmOffset(TDMOUT_CTRL0_OFFS)); }

 void AmlTdmOutDevice::FRDDREnable() {
   // Set the load bit, will make sure things start from beginning of buffer
   mmio_.SetBits32(1 << 12, GetFrddrOffset(FRDDR_CTRL1_OFFS));
   mmio_.SetBits32(1 << 31, GetFrddrOffset(FRDDR_CTRL0_OFFS));
 }

 void AmlTdmOutDevice::FRDDRDisable() {
   // Clear the load bit (this is the bit that forces the initial fetch of
   //    start address into current ptr)
   mmio_.ClearBits32(1 << 12, GetFrddrOffset(FRDDR_CTRL1_OFFS));
   // Disable the frddr channel
   mmio_.ClearBits32(1 << 31, GetFrddrOffset(FRDDR_CTRL0_OFFS));
 }

 void AmlTdmOutDevice::Sync() {
   mmio_.ClearBits32(3 << 28, GetTdmOffset(TDMOUT_CTRL0_OFFS));
   mmio_.SetBits32(1 << 29, GetTdmOffset(TDMOUT_CTRL0_OFFS));
   mmio_.SetBits32(1 << 28, GetTdmOffset(TDMOUT_CTRL0_OFFS));
 }

 // Resets frddr mechanisms to start at beginning of buffer
 //   starts the frddr (this will fill the fifo)
 //   starts the tdm to clock out data on the bus
 // returns the start time
 uint64_t AmlTdmOutDevice::Start() {
   uint64_t a, b;

   Sync();
   FRDDREnable();
   a = zx_clock_get_monotonic();
   TdmOutEnable();
   b = zx_clock_get_monotonic();
   return ((b - a) >> 1) + a;
 }

 void AmlTdmOutDevice::Stop() {
   TdmOutDisable();
   FRDDRDisable();
 }

 void AmlTdmOutDevice::Shutdown() {
   Stop();

   // Disable the output signals
   zx_off_t ptr = EE_AUDIO_CLK_TDMOUT_A_CTL + tdm_ch_ * sizeof(uint32_t);
   mmio_.ClearBits32(0x03 << 30, ptr);

   // Disable the audio domain clocks used by this instance.
   AudioClkDis((EE_AUDIO_CLK_GATE_TDMOUTA << tdm_ch_) | (EE_AUDIO_CLK_GATE_FRDDRA << frddr_ch_));

   // Note: We are leaving the ARB unit clocked as well as MCLK and
   //  SCLK generation units since it is possible they are used by
   //  some other audio driver outside of this instance
 }
	// Copyright 2018 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 <limits>
	#include <memory>
	#include <utility>

	#include <ddk/debug.h>
	#include <fbl/alloc_checker.h>
	#include <soc/aml-common/aml-tdm-audio.h>

	// static
	std::unique_ptr<AmlTdmDevice> AmlTdmOutDevice::Create(ddk::MmioBuffer mmio, ee_audio_mclk_src_t src,
	aml_tdm_out_t tdm, aml_frddr_t frddr,
	aml_tdm_mclk_t mclk,
	metadata::AmlVersion version) {
	// FRDDR A has 256 64-bit lines in the FIFO, B and C have 128.
	uint32_t fifo_depth = 128 * 8; // in bytes.
	if (frddr == FRDDR_A) {
	fifo_depth = 256 * 8;
	}

	fbl::AllocChecker ac;
	auto dev = std::unique_ptr<AmlTdmDevice>(
	new (&ac) AmlTdmOutDevice(std::move(mmio), src, tdm, frddr, mclk, fifo_depth, version));
	if (!ac.check()) {
	return nullptr;
	}

	return dev;
	}

	void AmlTdmOutDevice::Initialize() {
	// Enable the audio domain clocks used by this instance.
	AudioClkEna((EE_AUDIO_CLK_GATE_TDMOUTA << tdm_ch_) \| (EE_AUDIO_CLK_GATE_FRDDRA << frddr_ch_) \|
	EE_AUDIO_CLK_GATE_ARB);

	InitMclk();

	// Set the sclk and lrclk sources to the chosen mclk channel
	zx_off_t ptr = EE_AUDIO_CLK_TDMOUT_A_CTL + tdm_ch_ * sizeof(uint32_t);

	// We set the Frame Sync sclk invert bit that shifts the delta between FS and DATA, and
	// allows FS of width 1.
	constexpr uint32_t sclk_ws_inv = 1;
	mmio_.Write32((0x03 << 30) \| (sclk_ws_inv << 28) \| (mclk_ch_ << 24) \| (mclk_ch_ << 20), ptr);

	// Enable DDR ARB, and enable this ddr channels bit.
	mmio_.SetBits32((1 << 31) \| (1 << (4 + frddr_ch_)), EE_AUDIO_ARB_CTRL);

	// Disable the FRDDR Channel
	// Only use one buffer
	// Interrupts off
	// ack delay = 0
	// set destination tdm block and enable that selection
	switch (version_) {
	case metadata::AmlVersion::kS905D2G:
	mmio_.Write32(tdm_ch_ \| (1 << 3), GetFrddrOffset(FRDDR_CTRL0_OFFS));
	break;
	case metadata::AmlVersion::kS905D3G:
	mmio_.Write32(tdm_ch_ \| (1 << 4), GetFrddrOffset(FRDDR_CTRL2_OFFS_D3G));
	break;
	}
	// use entire fifo, start transfer request when fifo is at 1/2 full
	// set the magic force end bit(12) to cause fetch from start
	// -this only happens when the bit is set from 0->1 (edge)
	// fifo depth needs to be configured in terms of 64-bit lines.
	mmio_.Write32((1 << 12) \| (((fifo_depth_ / 8) - 1) << 24) \| ((((fifo_depth_ / 8) / 2) - 1) << 16),
	GetFrddrOffset(FRDDR_CTRL1_OFFS));

	// Value to be inserted in a slot if it is muted
	mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE_VAL_OFFS));
	// Value to be inserted in a slot if it is masked
	mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MASK_VAL_OFFS));

	mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE0_OFFS)); // Disable lane 0 muting.
	mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE1_OFFS)); // Disable lane 1 muting.
	mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE2_OFFS)); // Disable lane 2 muting.
	mmio_.Write32(0x00000000, GetTdmOffset(TDMOUT_MUTE3_OFFS)); // Disable lane 3 muting.

	// Datasheets state that PAD_CTRL1 controls sclk and lrclk source selection (which mclk),
	// it does this per pad (0, 1, 2). These pads are tied to the TDM channel in use
	// (this is not specified in the datasheets but confirmed empirically) such that TDM_OUT_A
	// corresponds to pad 0, TDM_OUT_B to pad 1, and TDM_OUT_C to pad 2.
	uint32_t pad1 = {};
	switch (version_) {
	case metadata::AmlVersion::kS905D2G:
	pad1 = EE_AUDIO_MST_PAD_CTRL1;
	break;
	case metadata::AmlVersion::kS905D3G:
	pad1 = EE_AUDIO_MST_PAD_CTRL1_D3G;
	break;
	}
	switch (tdm_ch_) {
	case TDM_OUT_A:
	mmio_.Write32((mclk_ch_ << 16) \| (mclk_ch_ << 0), pad1);
	break;
	case TDM_OUT_B:
	mmio_.Write32((mclk_ch_ << 20) \| (mclk_ch_ << 4), pad1);
	break;
	case TDM_OUT_C:
	mmio_.Write32((mclk_ch_ << 24) \| (mclk_ch_ << 8), pad1);
	break;
	}
	}

	uint32_t AmlTdmOutDevice::GetRingPosition() {
	return mmio_.Read32(GetFrddrOffset(FRDDR_STATUS2_OFFS)) -
	mmio_.Read32(GetFrddrOffset(FRDDR_START_ADDR_OFFS));
	}

	zx_status_t AmlTdmOutDevice::SetBuffer(zx_paddr_t buf, size_t len) {
	// Ensure ring buffer resides in lower memory (dma pointers are 32-bit)
	// and len is at least 8 (size of each dma operation)
	if (((buf + len - 1) > std::numeric_limits<uint32_t>::max()) \|\| (len < 8)) {
	return ZX_ERR_INVALID_ARGS;
	}

	// Write32 the start and end pointers. Each fetch is 64-bits, so end pointer
	// is pointer to the last 64-bit fetch (inclusive)
	mmio_.Write32(static_cast<uint32_t>(buf), GetFrddrOffset(FRDDR_START_ADDR_OFFS));
	mmio_.Write32(static_cast<uint32_t>(buf + len - 8), GetFrddrOffset(FRDDR_FINISH_ADDR_OFFS));
	return ZX_OK;
	}

	/*
	bit_offset - bit position in frame where first slot will appear
	(position 0 is concurrent with frame sync)
	num_slots - number of slots per frame minus one
	bits_per_slot - width of each slot minus one
	bits_per_sample - number of bits in sample minus one
	mix_mask - lanes to mix L+R.
	*/
	void AmlTdmOutDevice::ConfigTdmSlot(uint8_t bit_offset, uint8_t num_slots, uint8_t bits_per_slot,
	uint8_t bits_per_sample, uint8_t mix_mask, bool i2s_mode) {
	switch (version_) {
	case metadata::AmlVersion::kS905D2G: {
	uint32_t reg0 = bits_per_slot \| (num_slots << 5) \| (bit_offset << 15) \| (mix_mask << 20);
	mmio_.Write32(reg0, GetTdmOffset(TDMOUT_CTRL0_OFFS));
	} break;
	case metadata::AmlVersion::kS905D3G: {
	uint32_t reg0 =
	bits_per_slot \| (num_slots << 5) \| (bit_offset << 15) \| (1 << 31); // Bit 31 to enable.
	mmio_.Write32(reg0, GetTdmOffset(TDMOUT_CTRL0_OFFS));
	uint32_t reg2 = (mix_mask << 0);
	mmio_.Write32(reg2, GetTdmOffset(TDMOUT_CTRL2_OFFS_D3G));
	} break;
	}

	uint32_t reg = (bits_per_sample << 8) \| (frddr_ch_ << 24);
	if (bits_per_sample <= 8) {
	// 8 bit sample, left justify in frame, split 64-bit dma fetch into 8 samples
	reg \|= (0 << 4);
	} else if (bits_per_sample <= 16) {
	// 16 bit sample, left justify in frame, split 64-bit dma fetch into 4 samples
	reg \|= (2 << 4);
	} else {
	// 32/24 bit sample, left justify in slot, split 64-bit dma fetch into 2 samples
	reg \|= (4 << 4);
	}
	mmio_.Write32(reg, GetTdmOffset(TDMOUT_CTRL1_OFFS));
	}

	zx_status_t AmlTdmOutDevice::ConfigTdmLane(size_t lane, uint32_t enable_mask, uint32_t mute_mask) {
	switch (lane) {
	case 0:
	mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK0_OFFS));
	mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE0_OFFS));
	break;
	case 1:
	mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK1_OFFS));
	mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE1_OFFS));
	break;
	case 2:
	mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK2_OFFS));
	mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE2_OFFS));
	break;
	case 3:
	mmio_.Write32(enable_mask, GetTdmOffset(TDMOUT_MASK3_OFFS));
	mmio_.Write32(mute_mask, GetTdmOffset(TDMOUT_MUTE3_OFFS));
	break;
	default:
	return ZX_ERR_INVALID_ARGS;
	}
	return ZX_OK;
	}

	void AmlTdmOutDevice::ConfigTdmSwaps(uint32_t swaps) {
	mmio_.Write32(swaps, GetTdmOffset(TDMOUT_SWAP_OFFS));
	}

	// Stops the tdm from clocking data out of fifo onto bus
	void AmlTdmOutDevice::TdmOutDisable() {
	mmio_.ClearBits32(1 << 31, GetTdmOffset(TDMOUT_CTRL0_OFFS));
	}
	// Enables the tdm to clock data out of fifo onto bus
	void AmlTdmOutDevice::TdmOutEnable() { mmio_.SetBits32(1 << 31, GetTdmOffset(TDMOUT_CTRL0_OFFS)); }

	void AmlTdmOutDevice::FRDDREnable() {
	// Set the load bit, will make sure things start from beginning of buffer
	mmio_.SetBits32(1 << 12, GetFrddrOffset(FRDDR_CTRL1_OFFS));
	mmio_.SetBits32(1 << 31, GetFrddrOffset(FRDDR_CTRL0_OFFS));
	}

	void AmlTdmOutDevice::FRDDRDisable() {
	// Clear the load bit (this is the bit that forces the initial fetch of
	// start address into current ptr)
	mmio_.ClearBits32(1 << 12, GetFrddrOffset(FRDDR_CTRL1_OFFS));
	// Disable the frddr channel
	mmio_.ClearBits32(1 << 31, GetFrddrOffset(FRDDR_CTRL0_OFFS));
	}

	void AmlTdmOutDevice::Sync() {
	mmio_.ClearBits32(3 << 28, GetTdmOffset(TDMOUT_CTRL0_OFFS));
	mmio_.SetBits32(1 << 29, GetTdmOffset(TDMOUT_CTRL0_OFFS));
	mmio_.SetBits32(1 << 28, GetTdmOffset(TDMOUT_CTRL0_OFFS));
	}

	// Resets frddr mechanisms to start at beginning of buffer
	// starts the frddr (this will fill the fifo)
	// starts the tdm to clock out data on the bus
	// returns the start time
	uint64_t AmlTdmOutDevice::Start() {
	uint64_t a, b;

	Sync();
	FRDDREnable();
	a = zx_clock_get_monotonic();
	TdmOutEnable();
	b = zx_clock_get_monotonic();
	return ((b - a) >> 1) + a;
	}

	void AmlTdmOutDevice::Stop() {
	TdmOutDisable();
	FRDDRDisable();
	}

	void AmlTdmOutDevice::Shutdown() {
	Stop();

	// Disable the output signals
	zx_off_t ptr = EE_AUDIO_CLK_TDMOUT_A_CTL + tdm_ch_ * sizeof(uint32_t);
	mmio_.ClearBits32(0x03 << 30, ptr);

	// Disable the audio domain clocks used by this instance.
	AudioClkDis((EE_AUDIO_CLK_GATE_TDMOUTA << tdm_ch_) \| (EE_AUDIO_CLK_GATE_FRDDRA << frddr_ch_));

	// Note: We are leaving the ARB unit clocked as well as MCLK and
	// SCLK generation units since it is possible they are used by
	// some other audio driver outside of this instance
	}