pci/aw2/aw2-saa7146.c

8c2ecf20Sopenharmony_ci// SPDX-License-Identifier: GPL-2.0-only
8c2ecf20Sopenharmony_ci/*****************************************************************************
8c2ecf20Sopenharmony_ci *
8c2ecf20Sopenharmony_ci * Copyright (C) 2008 Cedric Bregardis <cedric.bregardis@free.fr> and
8c2ecf20Sopenharmony_ci * Jean-Christian Hassler <jhassler@free.fr>
8c2ecf20Sopenharmony_ci *
8c2ecf20Sopenharmony_ci * This file is part of the Audiowerk2 ALSA driver
8c2ecf20Sopenharmony_ci *
8c2ecf20Sopenharmony_ci *****************************************************************************/
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci#define AW2_SAA7146_M
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci#include <linux/init.h>
8c2ecf20Sopenharmony_ci#include <linux/pci.h>
8c2ecf20Sopenharmony_ci#include <linux/interrupt.h>
8c2ecf20Sopenharmony_ci#include <linux/delay.h>
8c2ecf20Sopenharmony_ci#include <linux/io.h>
8c2ecf20Sopenharmony_ci#include <sound/core.h>
8c2ecf20Sopenharmony_ci#include <sound/initval.h>
8c2ecf20Sopenharmony_ci#include <sound/pcm.h>
8c2ecf20Sopenharmony_ci#include <sound/pcm_params.h>
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci#include "saa7146.h"
8c2ecf20Sopenharmony_ci#include "aw2-saa7146.h"
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci#include "aw2-tsl.c"
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci#define WRITEREG(value, addr) writel((value), chip->base_addr + (addr))
8c2ecf20Sopenharmony_ci#define READREG(addr) readl(chip->base_addr + (addr))
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_cistatic struct snd_aw2_saa7146_cb_param
8c2ecf20Sopenharmony_ci arr_substream_it_playback_cb[NB_STREAM_PLAYBACK];
8c2ecf20Sopenharmony_cistatic struct snd_aw2_saa7146_cb_param
8c2ecf20Sopenharmony_ci arr_substream_it_capture_cb[NB_STREAM_CAPTURE];
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_cistatic int snd_aw2_saa7146_get_limit(int size);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci/* chip-specific destructor */
8c2ecf20Sopenharmony_ciint snd_aw2_saa7146_free(struct snd_aw2_saa7146 *chip)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	/* disable all irqs */
8c2ecf20Sopenharmony_ci	WRITEREG(0, IER);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* reset saa7146 */
8c2ecf20Sopenharmony_ci	WRITEREG((MRST_N << 16), MC1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* Unset base addr */
8c2ecf20Sopenharmony_ci	chip->base_addr = NULL;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	return 0;
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_setup(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci			   void __iomem *pci_base_addr)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	/* set PCI burst/threshold
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	   Burst length definition
8c2ecf20Sopenharmony_ci	   VALUE    BURST LENGTH
8c2ecf20Sopenharmony_ci	   000      1 Dword
8c2ecf20Sopenharmony_ci	   001      2 Dwords
8c2ecf20Sopenharmony_ci	   010      4 Dwords
8c2ecf20Sopenharmony_ci	   011      8 Dwords
8c2ecf20Sopenharmony_ci	   100      16 Dwords
8c2ecf20Sopenharmony_ci	   101      32 Dwords
8c2ecf20Sopenharmony_ci	   110      64 Dwords
8c2ecf20Sopenharmony_ci	   111      128 Dwords
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	   Threshold definition
8c2ecf20Sopenharmony_ci	   VALUE    WRITE MODE              READ MODE
8c2ecf20Sopenharmony_ci	   00       1 Dword of valid data   1 empty Dword
8c2ecf20Sopenharmony_ci	   01       4 Dwords of valid data  4 empty Dwords
8c2ecf20Sopenharmony_ci	   10       8 Dwords of valid data  8 empty Dwords
8c2ecf20Sopenharmony_ci	   11       16 Dwords of valid data 16 empty Dwords */
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	unsigned int acon2;
8c2ecf20Sopenharmony_ci	unsigned int acon1 = 0;
8c2ecf20Sopenharmony_ci	int i;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* Set base addr */
8c2ecf20Sopenharmony_ci	chip->base_addr = pci_base_addr;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* disable all irqs */
8c2ecf20Sopenharmony_ci	WRITEREG(0, IER);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* reset saa7146 */
8c2ecf20Sopenharmony_ci	WRITEREG((MRST_N << 16), MC1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* enable audio interface */
8c2ecf20Sopenharmony_ci#ifdef __BIG_ENDIAN
8c2ecf20Sopenharmony_ci	acon1 |= A1_SWAP;
8c2ecf20Sopenharmony_ci	acon1 |= A2_SWAP;
8c2ecf20Sopenharmony_ci#endif
8c2ecf20Sopenharmony_ci	/* WS0_CTRL, WS0_SYNC: input TSL1, I2S */
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* At initialization WS1 and WS2 are disabled (configured as input) */
8c2ecf20Sopenharmony_ci	acon1 |= 0 * WS1_CTRL;
8c2ecf20Sopenharmony_ci	acon1 |= 0 * WS2_CTRL;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* WS4 is not used. So it must not restart A2.
8c2ecf20Sopenharmony_ci	   This is why it is configured as output (force to low) */
8c2ecf20Sopenharmony_ci	acon1 |= 3 * WS4_CTRL;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* WS3_CTRL, WS3_SYNC: output TSL2, I2S */
8c2ecf20Sopenharmony_ci	acon1 |= 2 * WS3_CTRL;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* A1 and A2 are active and asynchronous */
8c2ecf20Sopenharmony_ci	acon1 |= 3 * AUDIO_MODE;
8c2ecf20Sopenharmony_ci	WRITEREG(acon1, ACON1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* The following comes from original windows driver.
8c2ecf20Sopenharmony_ci	   It is needed to have a correct behavior of input and output
8c2ecf20Sopenharmony_ci	   simultenously, but I don't know why ! */
8c2ecf20Sopenharmony_ci	WRITEREG(3 * (BurstA1_in) + 3 * (ThreshA1_in) +
8c2ecf20Sopenharmony_ci		 3 * (BurstA1_out) + 3 * (ThreshA1_out) +
8c2ecf20Sopenharmony_ci		 3 * (BurstA2_out) + 3 * (ThreshA2_out), PCI_BT_A);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* enable audio port pins */
8c2ecf20Sopenharmony_ci	WRITEREG((EAP << 16) | EAP, MC1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* enable I2C */
8c2ecf20Sopenharmony_ci	WRITEREG((EI2C << 16) | EI2C, MC1);
8c2ecf20Sopenharmony_ci	/* enable interrupts */
8c2ecf20Sopenharmony_ci	WRITEREG(A1_out | A2_out | A1_in | IIC_S | IIC_E, IER);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* audio configuration */
8c2ecf20Sopenharmony_ci	acon2 = A2_CLKSRC | BCLK1_OEN;
8c2ecf20Sopenharmony_ci	WRITEREG(acon2, ACON2);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* By default use analog input */
8c2ecf20Sopenharmony_ci	snd_aw2_saa7146_use_digital_input(chip, 0);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* TSL setup */
8c2ecf20Sopenharmony_ci	for (i = 0; i < 8; ++i) {
8c2ecf20Sopenharmony_ci		WRITEREG(tsl1[i], TSL1 + (i * 4));
8c2ecf20Sopenharmony_ci		WRITEREG(tsl2[i], TSL2 + (i * 4));
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_pcm_init_playback(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci				       int stream_number,
8c2ecf20Sopenharmony_ci				       unsigned long dma_addr,
8c2ecf20Sopenharmony_ci				       unsigned long period_size,
8c2ecf20Sopenharmony_ci				       unsigned long buffer_size)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	unsigned long dw_page, dw_limit;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* Configure DMA for substream
8c2ecf20Sopenharmony_ci	   Configuration informations: ALSA has allocated continuous memory
8c2ecf20Sopenharmony_ci	   pages. So we don't need to use MMU of saa7146.
8c2ecf20Sopenharmony_ci	 */
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* No MMU -> nothing to do with PageA1, we only configure the limit of
8c2ecf20Sopenharmony_ci	   PageAx_out register */
8c2ecf20Sopenharmony_ci	/* Disable MMU */
8c2ecf20Sopenharmony_ci	dw_page = (0L << 11);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* Configure Limit for DMA access.
8c2ecf20Sopenharmony_ci	   The limit register defines an address limit, which generates
8c2ecf20Sopenharmony_ci	   an interrupt if passed by the actual PCI address pointer.
8c2ecf20Sopenharmony_ci	   '0001' means an interrupt will be generated if the lower
8c2ecf20Sopenharmony_ci	   6 bits (64 bytes) of the PCI address are zero. '0010'
8c2ecf20Sopenharmony_ci	   defines a limit of 128 bytes, '0011' one of 256 bytes, and
8c2ecf20Sopenharmony_ci	   so on up to 1 Mbyte defined by '1111'. This interrupt range
8c2ecf20Sopenharmony_ci	   can be calculated as follows:
8c2ecf20Sopenharmony_ci	   Range = 2^(5 + Limit) bytes.
8c2ecf20Sopenharmony_ci	 */
8c2ecf20Sopenharmony_ci	dw_limit = snd_aw2_saa7146_get_limit(period_size);
8c2ecf20Sopenharmony_ci	dw_page |= (dw_limit << 4);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	if (stream_number == 0) {
8c2ecf20Sopenharmony_ci		WRITEREG(dw_page, PageA2_out);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* Base address for DMA transfert. */
8c2ecf20Sopenharmony_ci		/* This address has been reserved by ALSA. */
8c2ecf20Sopenharmony_ci		/* This is a physical address */
8c2ecf20Sopenharmony_ci		WRITEREG(dma_addr, BaseA2_out);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* Define upper limit for DMA access */
8c2ecf20Sopenharmony_ci		WRITEREG(dma_addr + buffer_size, ProtA2_out);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	} else if (stream_number == 1) {
8c2ecf20Sopenharmony_ci		WRITEREG(dw_page, PageA1_out);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* Base address for DMA transfert. */
8c2ecf20Sopenharmony_ci		/* This address has been reserved by ALSA. */
8c2ecf20Sopenharmony_ci		/* This is a physical address */
8c2ecf20Sopenharmony_ci		WRITEREG(dma_addr, BaseA1_out);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* Define upper limit for DMA access */
8c2ecf20Sopenharmony_ci		WRITEREG(dma_addr + buffer_size, ProtA1_out);
8c2ecf20Sopenharmony_ci	} else {
8c2ecf20Sopenharmony_ci		pr_err("aw2: snd_aw2_saa7146_pcm_init_playback: "
8c2ecf20Sopenharmony_ci		       "Substream number is not 0 or 1 -> not managed\n");
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_pcm_init_capture(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci				      int stream_number, unsigned long dma_addr,
8c2ecf20Sopenharmony_ci				      unsigned long period_size,
8c2ecf20Sopenharmony_ci				      unsigned long buffer_size)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	unsigned long dw_page, dw_limit;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* Configure DMA for substream
8c2ecf20Sopenharmony_ci	   Configuration informations: ALSA has allocated continuous memory
8c2ecf20Sopenharmony_ci	   pages. So we don't need to use MMU of saa7146.
8c2ecf20Sopenharmony_ci	 */
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* No MMU -> nothing to do with PageA1, we only configure the limit of
8c2ecf20Sopenharmony_ci	   PageAx_out register */
8c2ecf20Sopenharmony_ci	/* Disable MMU */
8c2ecf20Sopenharmony_ci	dw_page = (0L << 11);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	/* Configure Limit for DMA access.
8c2ecf20Sopenharmony_ci	   The limit register defines an address limit, which generates
8c2ecf20Sopenharmony_ci	   an interrupt if passed by the actual PCI address pointer.
8c2ecf20Sopenharmony_ci	   '0001' means an interrupt will be generated if the lower
8c2ecf20Sopenharmony_ci	   6 bits (64 bytes) of the PCI address are zero. '0010'
8c2ecf20Sopenharmony_ci	   defines a limit of 128 bytes, '0011' one of 256 bytes, and
8c2ecf20Sopenharmony_ci	   so on up to 1 Mbyte defined by '1111'. This interrupt range
8c2ecf20Sopenharmony_ci	   can be calculated as follows:
8c2ecf20Sopenharmony_ci	   Range = 2^(5 + Limit) bytes.
8c2ecf20Sopenharmony_ci	 */
8c2ecf20Sopenharmony_ci	dw_limit = snd_aw2_saa7146_get_limit(period_size);
8c2ecf20Sopenharmony_ci	dw_page |= (dw_limit << 4);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	if (stream_number == 0) {
8c2ecf20Sopenharmony_ci		WRITEREG(dw_page, PageA1_in);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* Base address for DMA transfert. */
8c2ecf20Sopenharmony_ci		/* This address has been reserved by ALSA. */
8c2ecf20Sopenharmony_ci		/* This is a physical address */
8c2ecf20Sopenharmony_ci		WRITEREG(dma_addr, BaseA1_in);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* Define upper limit for DMA access  */
8c2ecf20Sopenharmony_ci		WRITEREG(dma_addr + buffer_size, ProtA1_in);
8c2ecf20Sopenharmony_ci	} else {
8c2ecf20Sopenharmony_ci		pr_err("aw2: snd_aw2_saa7146_pcm_init_capture: "
8c2ecf20Sopenharmony_ci		       "Substream number is not 0 -> not managed\n");
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_define_it_playback_callback(unsigned int stream_number,
8c2ecf20Sopenharmony_ci						 snd_aw2_saa7146_it_cb
8c2ecf20Sopenharmony_ci						 p_it_callback,
8c2ecf20Sopenharmony_ci						 void *p_callback_param)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	if (stream_number < NB_STREAM_PLAYBACK) {
8c2ecf20Sopenharmony_ci		arr_substream_it_playback_cb[stream_number].p_it_callback =
8c2ecf20Sopenharmony_ci		    (snd_aw2_saa7146_it_cb) p_it_callback;
8c2ecf20Sopenharmony_ci		arr_substream_it_playback_cb[stream_number].p_callback_param =
8c2ecf20Sopenharmony_ci		    (void *)p_callback_param;
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_define_it_capture_callback(unsigned int stream_number,
8c2ecf20Sopenharmony_ci						snd_aw2_saa7146_it_cb
8c2ecf20Sopenharmony_ci						p_it_callback,
8c2ecf20Sopenharmony_ci						void *p_callback_param)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	if (stream_number < NB_STREAM_CAPTURE) {
8c2ecf20Sopenharmony_ci		arr_substream_it_capture_cb[stream_number].p_it_callback =
8c2ecf20Sopenharmony_ci		    (snd_aw2_saa7146_it_cb) p_it_callback;
8c2ecf20Sopenharmony_ci		arr_substream_it_capture_cb[stream_number].p_callback_param =
8c2ecf20Sopenharmony_ci		    (void *)p_callback_param;
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_pcm_trigger_start_playback(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci						int stream_number)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	unsigned int acon1 = 0;
8c2ecf20Sopenharmony_ci	/* In aw8 driver, dma transfert is always active. It is
8c2ecf20Sopenharmony_ci	   started and stopped in a larger "space" */
8c2ecf20Sopenharmony_ci	acon1 = READREG(ACON1);
8c2ecf20Sopenharmony_ci	if (stream_number == 0) {
8c2ecf20Sopenharmony_ci		WRITEREG((TR_E_A2_OUT << 16) | TR_E_A2_OUT, MC1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* WS2_CTRL, WS2_SYNC: output TSL2, I2S */
8c2ecf20Sopenharmony_ci		acon1 |= 2 * WS2_CTRL;
8c2ecf20Sopenharmony_ci		WRITEREG(acon1, ACON1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	} else if (stream_number == 1) {
8c2ecf20Sopenharmony_ci		WRITEREG((TR_E_A1_OUT << 16) | TR_E_A1_OUT, MC1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		/* WS1_CTRL, WS1_SYNC: output TSL1, I2S */
8c2ecf20Sopenharmony_ci		acon1 |= 1 * WS1_CTRL;
8c2ecf20Sopenharmony_ci		WRITEREG(acon1, ACON1);
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_pcm_trigger_stop_playback(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci					       int stream_number)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	unsigned int acon1 = 0;
8c2ecf20Sopenharmony_ci	acon1 = READREG(ACON1);
8c2ecf20Sopenharmony_ci	if (stream_number == 0) {
8c2ecf20Sopenharmony_ci		/* WS2_CTRL, WS2_SYNC: output TSL2, I2S */
8c2ecf20Sopenharmony_ci		acon1 &= ~(3 * WS2_CTRL);
8c2ecf20Sopenharmony_ci		WRITEREG(acon1, ACON1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		WRITEREG((TR_E_A2_OUT << 16), MC1);
8c2ecf20Sopenharmony_ci	} else if (stream_number == 1) {
8c2ecf20Sopenharmony_ci		/* WS1_CTRL, WS1_SYNC: output TSL1, I2S */
8c2ecf20Sopenharmony_ci		acon1 &= ~(3 * WS1_CTRL);
8c2ecf20Sopenharmony_ci		WRITEREG(acon1, ACON1);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		WRITEREG((TR_E_A1_OUT << 16), MC1);
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_pcm_trigger_start_capture(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci					       int stream_number)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	/* In aw8 driver, dma transfert is always active. It is
8c2ecf20Sopenharmony_ci	   started and stopped in a larger "space" */
8c2ecf20Sopenharmony_ci	if (stream_number == 0)
8c2ecf20Sopenharmony_ci		WRITEREG((TR_E_A1_IN << 16) | TR_E_A1_IN, MC1);
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_pcm_trigger_stop_capture(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci					      int stream_number)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	if (stream_number == 0)
8c2ecf20Sopenharmony_ci		WRITEREG((TR_E_A1_IN << 16), MC1);
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ciirqreturn_t snd_aw2_saa7146_interrupt(int irq, void *dev_id)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	unsigned int isr;
8c2ecf20Sopenharmony_ci	__always_unused unsigned int iicsta;
8c2ecf20Sopenharmony_ci	struct snd_aw2_saa7146 *chip = dev_id;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	isr = READREG(ISR);
8c2ecf20Sopenharmony_ci	if (!isr)
8c2ecf20Sopenharmony_ci		return IRQ_NONE;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	WRITEREG(isr, ISR);
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	if (isr & (IIC_S | IIC_E)) {
8c2ecf20Sopenharmony_ci		iicsta = READREG(IICSTA);
8c2ecf20Sopenharmony_ci		WRITEREG(0x100, IICSTA);
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	if (isr & A1_out) {
8c2ecf20Sopenharmony_ci		if (arr_substream_it_playback_cb[1].p_it_callback != NULL) {
8c2ecf20Sopenharmony_ci			arr_substream_it_playback_cb[1].
8c2ecf20Sopenharmony_ci			    p_it_callback(arr_substream_it_playback_cb[1].
8c2ecf20Sopenharmony_ci					  p_callback_param);
8c2ecf20Sopenharmony_ci		}
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	if (isr & A2_out) {
8c2ecf20Sopenharmony_ci		if (arr_substream_it_playback_cb[0].p_it_callback != NULL) {
8c2ecf20Sopenharmony_ci			arr_substream_it_playback_cb[0].
8c2ecf20Sopenharmony_ci			    p_it_callback(arr_substream_it_playback_cb[0].
8c2ecf20Sopenharmony_ci					  p_callback_param);
8c2ecf20Sopenharmony_ci		}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	if (isr & A1_in) {
8c2ecf20Sopenharmony_ci		if (arr_substream_it_capture_cb[0].p_it_callback != NULL) {
8c2ecf20Sopenharmony_ci			arr_substream_it_capture_cb[0].
8c2ecf20Sopenharmony_ci			    p_it_callback(arr_substream_it_capture_cb[0].
8c2ecf20Sopenharmony_ci					  p_callback_param);
8c2ecf20Sopenharmony_ci		}
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	return IRQ_HANDLED;
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ciunsigned int snd_aw2_saa7146_get_hw_ptr_playback(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci						 int stream_number,
8c2ecf20Sopenharmony_ci						 unsigned char *start_addr,
8c2ecf20Sopenharmony_ci						 unsigned int buffer_size)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	long pci_adp = 0;
8c2ecf20Sopenharmony_ci	size_t ptr = 0;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci	if (stream_number == 0) {
8c2ecf20Sopenharmony_ci		pci_adp = READREG(PCI_ADP3);
8c2ecf20Sopenharmony_ci		ptr = pci_adp - (long)start_addr;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		if (ptr == buffer_size)
8c2ecf20Sopenharmony_ci			ptr = 0;
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	if (stream_number == 1) {
8c2ecf20Sopenharmony_ci		pci_adp = READREG(PCI_ADP1);
8c2ecf20Sopenharmony_ci		ptr = pci_adp - (size_t) start_addr;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		if (ptr == buffer_size)
8c2ecf20Sopenharmony_ci			ptr = 0;
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	return ptr;
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ciunsigned int snd_aw2_saa7146_get_hw_ptr_capture(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci						int stream_number,
8c2ecf20Sopenharmony_ci						unsigned char *start_addr,
8c2ecf20Sopenharmony_ci						unsigned int buffer_size)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	size_t pci_adp = 0;
8c2ecf20Sopenharmony_ci	size_t ptr = 0;
8c2ecf20Sopenharmony_ci	if (stream_number == 0) {
8c2ecf20Sopenharmony_ci		pci_adp = READREG(PCI_ADP2);
8c2ecf20Sopenharmony_ci		ptr = pci_adp - (size_t) start_addr;
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci		if (ptr == buffer_size)
8c2ecf20Sopenharmony_ci			ptr = 0;
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	return ptr;
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_civoid snd_aw2_saa7146_use_digital_input(struct snd_aw2_saa7146 *chip,
8c2ecf20Sopenharmony_ci				       int use_digital)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	/* FIXME: switch between analog and digital input does not always work.
8c2ecf20Sopenharmony_ci	   It can produce a kind of white noise. It seams that received data
8c2ecf20Sopenharmony_ci	   are inverted sometime (endian inversion). Why ? I don't know, maybe
8c2ecf20Sopenharmony_ci	   a problem of synchronization... However for the time being I have
8c2ecf20Sopenharmony_ci	   not found the problem. Workaround: switch again (and again) between
8c2ecf20Sopenharmony_ci	   digital and analog input until it works. */
8c2ecf20Sopenharmony_ci	if (use_digital)
8c2ecf20Sopenharmony_ci		WRITEREG(0x40, GPIO_CTRL);
8c2ecf20Sopenharmony_ci	else
8c2ecf20Sopenharmony_ci		WRITEREG(0x50, GPIO_CTRL);
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ciint snd_aw2_saa7146_is_using_digital_input(struct snd_aw2_saa7146 *chip)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	unsigned int reg_val = READREG(GPIO_CTRL);
8c2ecf20Sopenharmony_ci	if ((reg_val & 0xFF) == 0x40)
8c2ecf20Sopenharmony_ci		return 1;
8c2ecf20Sopenharmony_ci	else
8c2ecf20Sopenharmony_ci		return 0;
8c2ecf20Sopenharmony_ci}
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_ci
8c2ecf20Sopenharmony_cistatic int snd_aw2_saa7146_get_limit(int size)
8c2ecf20Sopenharmony_ci{
8c2ecf20Sopenharmony_ci	int limitsize = 32;
8c2ecf20Sopenharmony_ci	int limit = 0;
8c2ecf20Sopenharmony_ci	while (limitsize < size) {
8c2ecf20Sopenharmony_ci		limitsize *= 2;
8c2ecf20Sopenharmony_ci		limit++;
8c2ecf20Sopenharmony_ci	}
8c2ecf20Sopenharmony_ci	return limit;
8c2ecf20Sopenharmony_ci}