ASoC: SOF: Add SKL/KBL support for IPC4 CI tests

	  Say Y if you have such a device.

	  If unsure select "N".

config SND_SOC_SOF_INTEL_SKL

	tristate

	select SND_SOC_SOF_HDA_COMMON

	select SND_SOC_SOF_INTEL_IPC4

config SND_SOC_SOF_SKYLAKE

	tristate "SOF support for SkyLake"

	default SND_SOC_SOF_PCI

	select SND_SOC_SOF_INTEL_SKL

	help

	  This adds support for the Intel(R) platforms using the SkyLake processors.

	  Say Y if you have such a device.

	  If unsure select "N".

	  This is intended only for developers and not a recommend option for distros.

config SND_SOC_SOF_KABYLAKE

	tristate "SOF support for KabyLake"

	default SND_SOC_SOF_PCI

	select SND_SOC_SOF_INTEL_SKL

	help

	  This adds support for the Intel(R) platforms using the KabyLake processors.

	  Say Y if you have such a device.

	  If unsure select "N".

	  This is intended only for developers and not a recommend option for distros.

config SND_SOC_SOF_INTEL_APL

	tristate

	select SND_SOC_SOF_HDA_COMMON

snd-sof-intel-hda-common-objs := hda.o hda-loader.o hda-stream.o hda-trace.o \

				 hda-dsp.o hda-ipc.o hda-ctrl.o hda-pcm.o \

				 hda-dai.o hda-bus.o \

				 skl.o hda-loader-skl.o \

				 apl.o cnl.o tgl.o icl.o mtl.o hda-common-ops.o

snd-sof-intel-hda-common-$(CONFIG_SND_SOC_SOF_HDA_PROBES) += hda-probes.o

snd-sof-intel-hda-objs := hda-codec.o

obj-$(CONFIG_SND_SOC_SOF_HDA) += snd-sof-intel-hda.o

snd-sof-pci-intel-tng-objs := pci-tng.o

snd-sof-pci-intel-skl-objs := pci-skl.o

snd-sof-pci-intel-apl-objs := pci-apl.o

snd-sof-pci-intel-cnl-objs := pci-cnl.o

snd-sof-pci-intel-icl-objs := pci-icl.o

snd-sof-pci-intel-mtl-objs := pci-mtl.o

obj-$(CONFIG_SND_SOC_SOF_MERRIFIELD) += snd-sof-pci-intel-tng.o

obj-$(CONFIG_SND_SOC_SOF_INTEL_SKL) += snd-sof-pci-intel-skl.o

obj-$(CONFIG_SND_SOC_SOF_INTEL_APL) += snd-sof-pci-intel-apl.o

obj-$(CONFIG_SND_SOC_SOF_INTEL_CNL) += snd-sof-pci-intel-cnl.o

obj-$(CONFIG_SND_SOC_SOF_INTEL_ICL) += snd-sof-pci-intel-icl.o

	return ret;

}

static int hda_dsp_core_stall_reset(struct snd_sof_dev *sdev, unsigned int core_mask)

int hda_dsp_core_stall_reset(struct snd_sof_dev *sdev, unsigned int core_mask)

{

	/* stall core */

	snd_sof_dsp_update_bits_unlocked(sdev, HDA_DSP_BAR,

	return hda_dsp_core_reset_enter(sdev, core_mask);

}

static bool hda_dsp_core_is_enabled(struct snd_sof_dev *sdev, unsigned int core_mask)

bool hda_dsp_core_is_enabled(struct snd_sof_dev *sdev, unsigned int core_mask)

{

	int val;

	bool is_enable;

/* Check if an IPC IRQ occurred */

bool hda_dsp_check_ipc_irq(struct snd_sof_dev *sdev)

{

	struct sof_intel_hda_dev *hda = sdev->pdata->hw_pdata;

	bool ret = false;

	u32 irq_status;

	if (irq_status & HDA_DSP_ADSPIS_IPC)

		ret = true;

	/* CLDMA message ? */

	if (irq_status & HDA_DSP_ADSPIS_CL_DMA) {

		hda->code_loading = 0;

		wake_up(&hda->waitq);

		ret = false;

	}

out:

	return ret;

}

// SPDX-License-Identifier: (GPL-2.0-only OR BSD-3-Clause)

//

// This file is provided under a dual BSD/GPLv2 license.  When using or

// redistributing this file, you may do so under either license.

//

// Copyright(c) 2018-2022 Intel Corporation. All rights reserved.

//

#include <linux/delay.h>

#include <linux/device.h>

#include <linux/dma-mapping.h>

#include <linux/firmware.h>

#include <linux/fs.h>

#include <linux/interrupt.h>

#include <linux/mm.h>

#include <linux/module.h>

#include <linux/pci.h>

#include <linux/pm_runtime.h>

#include <linux/slab.h>

#include <sound/hdaudio_ext.h>

#include <sound/sof.h>

#include <sound/pcm_params.h>

#include "../sof-priv.h"

#include "../ops.h"

#include "hda.h"

#define HDA_SKL_WAIT_TIMEOUT		500	/* 500 msec */

#define HDA_SKL_CLDMA_MAX_BUFFER_SIZE	(32 * PAGE_SIZE)

/* Stream Reset */

#define HDA_CL_SD_CTL_SRST_SHIFT	0

#define HDA_CL_SD_CTL_SRST(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_SRST_SHIFT)

/* Stream Run */

#define HDA_CL_SD_CTL_RUN_SHIFT		1

#define HDA_CL_SD_CTL_RUN(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_RUN_SHIFT)

/* Interrupt On Completion Enable */

#define HDA_CL_SD_CTL_IOCE_SHIFT	2

#define HDA_CL_SD_CTL_IOCE(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_IOCE_SHIFT)

/* FIFO Error Interrupt Enable */

#define HDA_CL_SD_CTL_FEIE_SHIFT	3

#define HDA_CL_SD_CTL_FEIE(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_FEIE_SHIFT)

/* Descriptor Error Interrupt Enable */

#define HDA_CL_SD_CTL_DEIE_SHIFT	4

#define HDA_CL_SD_CTL_DEIE(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_DEIE_SHIFT)

/* FIFO Limit Change */

#define HDA_CL_SD_CTL_FIFOLC_SHIFT	5

#define HDA_CL_SD_CTL_FIFOLC(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_FIFOLC_SHIFT)

/* Stripe Control */

#define HDA_CL_SD_CTL_STRIPE_SHIFT	16

#define HDA_CL_SD_CTL_STRIPE(x)		(((x) & 0x3) << \

					HDA_CL_SD_CTL_STRIPE_SHIFT)

/* Traffic Priority */

#define HDA_CL_SD_CTL_TP_SHIFT		18

#define HDA_CL_SD_CTL_TP(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_TP_SHIFT)

/* Bidirectional Direction Control */

#define HDA_CL_SD_CTL_DIR_SHIFT		19

#define HDA_CL_SD_CTL_DIR(x)		(((x) & 0x1) << \

					HDA_CL_SD_CTL_DIR_SHIFT)

/* Stream Number */

#define HDA_CL_SD_CTL_STRM_SHIFT	20

#define HDA_CL_SD_CTL_STRM(x)		(((x) & 0xf) << \

					HDA_CL_SD_CTL_STRM_SHIFT)

#define HDA_CL_SD_CTL_INT(x)	\

		(HDA_CL_SD_CTL_IOCE(x) | \

		HDA_CL_SD_CTL_FEIE(x) | \

		HDA_CL_SD_CTL_DEIE(x))

#define HDA_CL_SD_CTL_INT_MASK	\

		(HDA_CL_SD_CTL_IOCE(1) | \

		HDA_CL_SD_CTL_FEIE(1) | \

		HDA_CL_SD_CTL_DEIE(1))

#define DMA_ADDRESS_128_BITS_ALIGNMENT	7

#define BDL_ALIGN(x)			((x) >> DMA_ADDRESS_128_BITS_ALIGNMENT)

/* Buffer Descriptor List Lower Base Address */

#define HDA_CL_SD_BDLPLBA_SHIFT		7

#define HDA_CL_SD_BDLPLBA_MASK		GENMASK(31, 7)

#define HDA_CL_SD_BDLPLBA(x)		\

	((BDL_ALIGN(lower_32_bits(x)) << HDA_CL_SD_BDLPLBA_SHIFT) & \

	 HDA_CL_SD_BDLPLBA_MASK)

/* Buffer Descriptor List Upper Base Address */

#define HDA_CL_SD_BDLPUBA(x)		\

			(upper_32_bits(x))

/* Software Position in Buffer Enable */

#define HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_SHIFT	0

#define HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_MASK	\

			(1 << HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_SHIFT)

#define HDA_CL_SPBFIFO_SPBFCCTL_SPIBE(x)	\

			(((x) << HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_SHIFT) & \

			 HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_MASK)

#define HDA_CL_DMA_SD_INT_COMPLETE		0x4

static int cl_skl_cldma_setup_bdle(struct snd_sof_dev *sdev,

				   struct snd_dma_buffer *dmab_data,

				   __le32 **bdlp, int size, int with_ioc)

{

	phys_addr_t addr = virt_to_phys(dmab_data->area);

	__le32 *bdl = *bdlp;

	/*

	 * This code is simplified by using one fragment of physical memory and assuming

	 * all the code fits. This could be improved with scatter-gather but the firmware

	 * size is limited by DSP memory anyways

	 */

	bdl[0] = cpu_to_le32(lower_32_bits(addr));

	bdl[1] = cpu_to_le32(upper_32_bits(addr));

	bdl[2] = cpu_to_le32(size);

	bdl[3] = (!with_ioc) ? 0 : cpu_to_le32(0x01);

	return 1; /* one fragment */

}

static void cl_skl_cldma_stream_run(struct snd_sof_dev *sdev, bool enable)

{

	int sd_offset = SOF_HDA_ADSP_LOADER_BASE;

	unsigned char val;

	int retries;

	u32 run = enable ? 0x1 : 0;

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

				sd_offset + SOF_HDA_ADSP_REG_CL_SD_CTL,

				HDA_CL_SD_CTL_RUN(1), HDA_CL_SD_CTL_RUN(run));

	retries = 300;

	do {

		udelay(3);

		/* waiting for hardware to report the stream Run bit set */

		val = snd_sof_dsp_read(sdev, HDA_DSP_BAR,

				       sd_offset + SOF_HDA_ADSP_REG_CL_SD_CTL);

		val &= HDA_CL_SD_CTL_RUN(1);

		if (enable && val)

			break;

		else if (!enable && !val)

			break;

	} while (--retries);

	if (retries == 0)

		dev_err(sdev->dev, "%s: failed to set Run bit=%d enable=%d\n",

			__func__, val, enable);

}

static void cl_skl_cldma_stream_clear(struct snd_sof_dev *sdev)

{

	int sd_offset = SOF_HDA_ADSP_LOADER_BASE;

	/* make sure Run bit is cleared before setting stream register */

	cl_skl_cldma_stream_run(sdev, 0);

	/* Disable the Interrupt On Completion, FIFO Error Interrupt,

	 * Descriptor Error Interrupt and set the cldma stream number to 0.

	 */

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

				sd_offset + SOF_HDA_ADSP_REG_CL_SD_CTL,

				HDA_CL_SD_CTL_INT_MASK, HDA_CL_SD_CTL_INT(0));

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

				sd_offset + SOF_HDA_ADSP_REG_CL_SD_CTL,

				HDA_CL_SD_CTL_STRM(0xf), HDA_CL_SD_CTL_STRM(0));

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_BDLPL, HDA_CL_SD_BDLPLBA(0));

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_BDLPU, 0);

	/* Set the Cyclic Buffer Length to 0. */

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_CBL, 0);

	/* Set the Last Valid Index. */

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_LVI, 0);

}

static void cl_skl_cldma_setup_spb(struct snd_sof_dev *sdev,

				   unsigned int size, bool enable)

{

	int sd_offset = SOF_DSP_REG_CL_SPBFIFO;

	if (enable)

		snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

					sd_offset + SOF_HDA_ADSP_REG_CL_SPBFIFO_SPBFCCTL,

					HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_MASK,

					HDA_CL_SPBFIFO_SPBFCCTL_SPIBE(1));

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SPBFIFO_SPIB, size);

}

static void cl_skl_cldma_set_intr(struct snd_sof_dev *sdev, bool enable)

{

	u32 val = enable ? HDA_DSP_ADSPIC_CL_DMA : 0;

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR, HDA_DSP_REG_ADSPIC,

				HDA_DSP_ADSPIC_CL_DMA, val);

}

static void cl_skl_cldma_cleanup_spb(struct snd_sof_dev *sdev)

{

	int sd_offset = SOF_DSP_REG_CL_SPBFIFO;

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

				sd_offset + SOF_HDA_ADSP_REG_CL_SPBFIFO_SPBFCCTL,

				HDA_CL_SPBFIFO_SPBFCCTL_SPIBE_MASK,

				HDA_CL_SPBFIFO_SPBFCCTL_SPIBE(0));

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SPBFIFO_SPIB, 0);

}

static void cl_skl_cldma_setup_controller(struct snd_sof_dev *sdev,

					  struct snd_dma_buffer *dmab_bdl,

					  unsigned int max_size, u32 count)

{

	int sd_offset = SOF_HDA_ADSP_LOADER_BASE;

	/* Clear the stream first and then set it. */

	cl_skl_cldma_stream_clear(sdev);

	/* setting the stream register */

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_BDLPL,

			  HDA_CL_SD_BDLPLBA(dmab_bdl->addr));

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_BDLPU,

			  HDA_CL_SD_BDLPUBA(dmab_bdl->addr));

	/* Set the Cyclic Buffer Length. */

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_CBL, max_size);

	/* Set the Last Valid Index. */

	snd_sof_dsp_write(sdev, HDA_DSP_BAR,

			  sd_offset + SOF_HDA_ADSP_REG_CL_SD_LVI, count - 1);

	/* Set the Interrupt On Completion, FIFO Error Interrupt,

	 * Descriptor Error Interrupt and the cldma stream number.

	 */

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

				sd_offset + SOF_HDA_ADSP_REG_CL_SD_CTL,

				HDA_CL_SD_CTL_INT_MASK, HDA_CL_SD_CTL_INT(1));

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR,

				sd_offset + SOF_HDA_ADSP_REG_CL_SD_CTL,

				HDA_CL_SD_CTL_STRM(0xf),

				HDA_CL_SD_CTL_STRM(1));

}

static int cl_stream_prepare_skl(struct snd_sof_dev *sdev,

				 struct snd_dma_buffer *dmab,

				 struct snd_dma_buffer *dmab_bdl)

{

	unsigned int bufsize = HDA_SKL_CLDMA_MAX_BUFFER_SIZE;

	__le32 *bdl;

	int frags;

	int ret;

	ret = snd_dma_alloc_pages(SNDRV_DMA_TYPE_DEV, sdev->dev, bufsize, dmab);

	if (ret < 0) {

		dev_err(sdev->dev, "%s: failed to alloc fw buffer: %x\n", __func__, ret);

		return ret;

	}

	ret = snd_dma_alloc_pages(SNDRV_DMA_TYPE_DEV, sdev->dev, bufsize, dmab_bdl);

	if (ret < 0) {

		dev_err(sdev->dev, "%s: failed to alloc blde: %x\n", __func__, ret);

		snd_dma_free_pages(dmab);

		return ret;

	}

	bdl = (__le32 *)dmab_bdl->area;

	frags = cl_skl_cldma_setup_bdle(sdev, dmab, &bdl, bufsize, 1);

	cl_skl_cldma_setup_controller(sdev, dmab_bdl, bufsize, frags);

	return ret;

}

static void cl_cleanup_skl(struct snd_sof_dev *sdev,

			   struct snd_dma_buffer *dmab,

			   struct snd_dma_buffer *dmab_bdl)

{

	cl_skl_cldma_cleanup_spb(sdev);

	cl_skl_cldma_stream_clear(sdev);

	snd_dma_free_pages(dmab);

	snd_dma_free_pages(dmab_bdl);

}

static int cl_dsp_init_skl(struct snd_sof_dev *sdev,

			   struct snd_dma_buffer *dmab,

			   struct snd_dma_buffer *dmab_bdl)

{

	struct sof_intel_hda_dev *hda = sdev->pdata->hw_pdata;

	const struct sof_intel_dsp_desc *chip = hda->desc;

	unsigned int status;

	u32 flags;

	int ret;

	/* check if the init_core is already enabled, if yes, reset and make it run,

	 * if not, powerdown and enable it again.

	 */

	if (hda_dsp_core_is_enabled(sdev, chip->init_core_mask)) {

		/* if enabled, reset it, and run the init_core. */

		ret = hda_dsp_core_stall_reset(sdev, chip->init_core_mask);

		if (ret < 0)

			goto err;

		ret = hda_dsp_core_run(sdev, chip->init_core_mask);

		if (ret < 0) {

			dev_err(sdev->dev, "%s: dsp core start failed %d\n", __func__, ret);

			goto err;

		}

	} else {

		/* if not enabled, power down it first and then powerup and run

		 * the init_core.

		 */

		ret = hda_dsp_core_reset_power_down(sdev, chip->init_core_mask);

		if (ret < 0) {

			dev_err(sdev->dev, "%s: dsp core0 disable fail: %d\n", __func__, ret);

			goto err;

		}

		ret = hda_dsp_enable_core(sdev, chip->init_core_mask);

		if (ret < 0) {

			dev_err(sdev->dev, "%s: dsp core0 enable fail: %d\n", __func__, ret);

			goto err;

		}

	}

	/* prepare DMA for code loader stream */

	ret = cl_stream_prepare_skl(sdev, dmab, dmab_bdl);

	if (ret < 0) {

		dev_err(sdev->dev, "%s: dma prepare fw loading err: %x\n", __func__, ret);

		return ret;

	}

	/* enable the interrupt */

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR, HDA_DSP_REG_ADSPIC,

				HDA_DSP_ADSPIC_IPC, HDA_DSP_ADSPIC_IPC);

	/* enable IPC DONE interrupt */

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR, chip->ipc_ctl,

				HDA_DSP_REG_HIPCCTL_DONE,

				HDA_DSP_REG_HIPCCTL_DONE);

	/* enable IPC BUSY interrupt */

	snd_sof_dsp_update_bits(sdev, HDA_DSP_BAR, chip->ipc_ctl,

				HDA_DSP_REG_HIPCCTL_BUSY,

				HDA_DSP_REG_HIPCCTL_BUSY);

	/* polling the ROM init status information. */

	ret = snd_sof_dsp_read_poll_timeout(sdev, HDA_DSP_BAR,

					    chip->rom_status_reg, status,

					    (FSR_TO_STATE_CODE(status)

					     == FSR_STATE_INIT_DONE),

					    HDA_DSP_REG_POLL_INTERVAL_US,

					    chip->rom_init_timeout *

					    USEC_PER_MSEC);

	if (ret < 0)

		goto err;

	return ret;

err:

	flags = SOF_DBG_DUMP_PCI | SOF_DBG_DUMP_MBOX;

	snd_sof_dsp_dbg_dump(sdev, "Boot failed\n", flags);

	cl_cleanup_skl(sdev, dmab, dmab_bdl);

	hda_dsp_core_reset_power_down(sdev, chip->init_core_mask);

	return ret;

}

static void cl_skl_cldma_fill_buffer(struct snd_sof_dev *sdev,

				     struct snd_dma_buffer *dmab,

				     unsigned int bufsize,

				     unsigned int copysize,

				     const void *curr_pos,

				     bool intr_enable)

{

	struct sof_intel_hda_dev *hda = sdev->pdata->hw_pdata;

	/* copy the image into the buffer with the maximum buffer size. */

	unsigned int size = (bufsize == copysize) ? bufsize : copysize;

	memcpy(dmab->area, curr_pos, size);

	/* Set the wait condition for every load. */

	hda->code_loading = 1;

	/* Set the interrupt. */

	if (intr_enable)

		cl_skl_cldma_set_intr(sdev, true);

	/* Set the SPB. */

	cl_skl_cldma_setup_spb(sdev, size, true);

	/* Trigger the code loading stream. */

	cl_skl_cldma_stream_run(sdev, true);

}

static int cl_skl_cldma_wait_interruptible(struct snd_sof_dev *sdev,

					   bool intr_wait)

{

	struct sof_intel_hda_dev *hda = sdev->pdata->hw_pdata;

	const struct sof_intel_dsp_desc *chip = hda->desc;

	int sd_offset = SOF_HDA_ADSP_LOADER_BASE;

	u8 cl_dma_intr_status;

	/*

	 * Wait for CLDMA interrupt to inform the binary segment transfer is

	 * complete.

	 */

	if (!wait_event_timeout(hda->waitq, !hda->code_loading,

				msecs_to_jiffies(HDA_SKL_WAIT_TIMEOUT))) {

		dev_err(sdev->dev, "cldma copy timeout\n");

		dev_err(sdev->dev, "ROM code=%#x: FW status=%#x\n",

			snd_sof_dsp_read(sdev, HDA_DSP_BAR, HDA_DSP_SRAM_REG_ROM_ERROR),

			snd_sof_dsp_read(sdev, HDA_DSP_BAR, chip->rom_status_reg));

		return -EIO;

	}

	/* now check DMA interrupt status */

	cl_dma_intr_status = snd_sof_dsp_read(sdev, HDA_DSP_BAR,

					      sd_offset + SOF_HDA_ADSP_REG_CL_SD_STS);

	if (!(cl_dma_intr_status & HDA_CL_DMA_SD_INT_COMPLETE)) {

		dev_err(sdev->dev, "cldma copy failed\n");

		return -EIO;

	}

	dev_dbg(sdev->dev, "cldma buffer copy complete\n");

	return 0;

}

static int

cl_skl_cldma_copy_to_buf(struct snd_sof_dev *sdev,

			 struct snd_dma_buffer *dmab,

			 const void *bin,

			 u32 total_size, u32 bufsize)

{

	unsigned int bytes_left = total_size;

	const void *curr_pos = bin;

	int ret;

	if (total_size <= 0)

		return -EINVAL;

	while (bytes_left > 0) {

		if (bytes_left > bufsize) {

			dev_dbg(sdev->dev, "cldma copy %#x bytes\n", bufsize);

			cl_skl_cldma_fill_buffer(sdev, dmab, bufsize, bufsize, curr_pos, true);

			ret = cl_skl_cldma_wait_interruptible(sdev, false);

			if (ret < 0) {

				dev_err(sdev->dev, "%s: fw failed to load. %#x bytes remaining\n",

					__func__, bytes_left);

				return ret;

			}

			bytes_left -= bufsize;

			curr_pos += bufsize;

		} else {

			dev_dbg(sdev->dev, "cldma copy %#x bytes\n", bytes_left);

			cl_skl_cldma_set_intr(sdev, false);

			cl_skl_cldma_fill_buffer(sdev, dmab, bufsize, bytes_left, curr_pos, false);

			return 0;

		}

	}

	return bytes_left;

}

static int cl_copy_fw_skl(struct snd_sof_dev *sdev,

			  struct snd_dma_buffer *dmab)

{

	struct snd_sof_pdata *plat_data = sdev->pdata;

	const struct firmware *fw =  plat_data->fw;

	struct firmware stripped_firmware;

	unsigned int bufsize = HDA_SKL_CLDMA_MAX_BUFFER_SIZE;

	int ret;

	stripped_firmware.data = plat_data->fw->data + plat_data->fw_offset;

	stripped_firmware.size = plat_data->fw->size - plat_data->fw_offset;

	dev_dbg(sdev->dev, "firmware size: %#zx buffer size %#x\n", fw->size, bufsize);

	ret = cl_skl_cldma_copy_to_buf(sdev, dmab, stripped_firmware.data,

				       stripped_firmware.size, bufsize);

	if (ret < 0)

		dev_err(sdev->dev, "%s: fw copy failed %d\n", __func__, ret);

	return ret;

}

int hda_dsp_cl_boot_firmware_skl(struct snd_sof_dev *sdev)

{

	struct sof_intel_hda_dev *hda = sdev->pdata->hw_pdata;

	const struct sof_intel_dsp_desc *chip = hda->desc;

	struct snd_dma_buffer dmab_bdl;

	struct snd_dma_buffer dmab;

	unsigned int reg;

	u32 flags;

	int ret;

	ret = cl_dsp_init_skl(sdev, &dmab, &dmab_bdl);

	/* retry enabling core and ROM load. seemed to help */

	if (ret < 0) {

		ret = cl_dsp_init_skl(sdev, &dmab, &dmab_bdl);

		if (ret < 0) {

			dev_err(sdev->dev, "Error code=%#x: FW status=%#x\n",

				snd_sof_dsp_read(sdev, HDA_DSP_BAR, HDA_DSP_SRAM_REG_ROM_ERROR),

				snd_sof_dsp_read(sdev, HDA_DSP_BAR, chip->rom_status_reg));

			dev_err(sdev->dev, "Core En/ROM load fail:%d\n", ret);

			return ret;

		}

	}

	dev_dbg(sdev->dev, "ROM init successful\n");

	/* at this point DSP ROM has been initialized and should be ready for

	 * code loading and firmware boot

	 */

	ret = cl_copy_fw_skl(sdev, &dmab);

	if (ret < 0) {

		dev_err(sdev->dev, "%s: load firmware failed : %d\n", __func__, ret);

		goto err;

	}

	ret = snd_sof_dsp_read_poll_timeout(sdev, HDA_DSP_BAR,

					    chip->rom_status_reg, reg,

					    (FSR_TO_STATE_CODE(reg)

					     == FSR_STATE_ROM_BASEFW_ENTERED),

					    HDA_DSP_REG_POLL_INTERVAL_US,

					    HDA_DSP_BASEFW_TIMEOUT_US);

	dev_dbg(sdev->dev, "Firmware download successful, booting...\n");

	cl_skl_cldma_stream_run(sdev, false);

	cl_cleanup_skl(sdev, &dmab, &dmab_bdl);

	if (!ret)

		return chip->init_core_mask;

	return ret;

err:

	flags = SOF_DBG_DUMP_PCI | SOF_DBG_DUMP_MBOX;

	snd_sof_dsp_dbg_dump(sdev, "Boot failed\n", flags);

	/* power down DSP */

	hda_dsp_core_reset_power_down(sdev, chip->init_core_mask);

	cl_skl_cldma_stream_run(sdev, false);

	cl_cleanup_skl(sdev, &dmab, &dmab_bdl);

	dev_err(sdev->dev, "%s: load fw failed err: %d\n", __func__, ret);

	return ret;

}