drivers/block/ftide020.c - uboot/armada - Git at Google

 /*
  * Faraday FTIDE020 ATA Controller (AHB)
  *
  * (C) Copyright 2011 Andes Technology
  * Greentime Hu <greentime@andestech.com>
  * Macpaul Lin <macpaul@andestech.com>
  * Kuo-Wei Chou <kwchou@andestech.com>
  *
  * See file CREDITS for list of people who contributed to this
  * project.
  *
  * 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, write to the Free Software
  * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
  * MA 02111-1307 USA
  *
  */
 /* ftide020.c - ide support functions for the FTIDE020_S controller */

 #include <config.h>
 #include <common.h>
 #include <ata.h>
 #include <ide.h>
 #include <asm/io.h>
 #include <api_public.h>

 #include "ftide020.h"

 /* base address */
 #define FTIDE_BASE	CONFIG_SYS_ATA_BASE_ADDR

 /*
  * data address - The CMD and DATA use the same FIFO in FTIDE020_S
  *   FTIDE_DATA = CONFIG_SYS_ATA_BASE_ADDR + CONFIG_SYS_ATA_DATA_OFFSET
  *		= &ftide020->rw_fifo
  */
 #define FTIDE_DATA	(&ftide020->rw_fifo)

 /* command and data I/O macros */
 /* 0x0 - DATA FIFO */
 #define WRITE_DATA(x)	outl((x), &ftide020->rw_fifo)	/* 0x00 */
 #define READ_DATA()	inl(&ftide020->rw_fifo)		/* 0x00 */
 /* 0x04 - R: Status Reg, W: CMD_FIFO */
 #define WRITE_CMD(x)	outl((x), &ftide020->cmd_fifo)	/* 0x04 */
 #define READ_STATUS()	inl(&ftide020->cmd_fifo)	/* 0x04 */

 void ftide_set_device(int cx8, int dev)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;

 	WRITE_CMD(SET_DEV_CMD | IDE_SET_CX8(cx8) | dev);
 }

 unsigned char ide_read_register(int dev, unsigned int port)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;

 	ftide_set_device(0, dev);
 	WRITE_CMD(READ_REG_CMD | IDE_REG_CS_READ(CONFIG_IDE_REG_CS) |
 		IDE_REG_DA_WRITE(port));

 	return READ_DATA() & 0xff;
 }

 void ide_write_register(int dev, unsigned int port, unsigned char val)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;

 	ftide_set_device(0, dev);
 	WRITE_CMD(WRITE_REG_CMD | IDE_REG_CS_WRITE(CONFIG_IDE_REG_CS) |
 		IDE_REG_DA_WRITE(port) | val);
 }

 void ide_write_data(int dev, ulong *sect_buf, int words)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;

 	ftide_set_device(0, dev);
 	WRITE_CMD(WRITE_DATA_CMD | ((words << 2) - 1));

 	/* block write */
 	outsl(FTIDE_DATA, sect_buf, words);
 }

 void ide_read_data(int dev, ulong *sect_buf, int words)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;

 	ftide_set_device(0, dev);
 	WRITE_CMD(READ_DATA_CMD | ((words << 2) - 1));

 	/* block read */
 	insl(FTIDE_DATA, sect_buf, words);
 }

 void ftide_dfifo_ready(ulong *time)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;

 	while (!(READ_STATUS() & STATUS_RFE)) {
 		if (*time-- == 0)
 			break;

 		udelay(100);
 	}
 }

 extern ulong ide_bus_offset[CONFIG_SYS_IDE_MAXBUS];

 /* Reset_IDE_controller */
 static void reset_ide_controller(void)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;
 	unsigned int val;

 	val = inl(&ftide020->cr);

 	val |= CONTROL_RST;
 	outl(val, &ftide020->cr);

 	/* wait until reset OK, this is poor HW design */
 	mdelay(50);
 	val &= ~(CONTROL_RST);
 	outl(val, &ftide020->cr);

 	mdelay(50);
 	val |= CONTROL_SRST;
 	outl(val, &ftide020->cr);

 	/* wait until reset OK, this is poor HW design */
 	mdelay(50);
 	val &= ~(CONTROL_SRST);
 	outl(val, &ftide020->cr);

 	/* IORDY enable for PIO, for 2 device */
 	val |= (CONTROL_IRE0 | CONTROL_IRE1);
 	outl(val, &ftide020->cr);
 }

 /* IDE clock frequence */
 uint ftide_clock_freq(void)
 {
 	/*
 	 * todo: To aquire dynamic system frequency is dependend on the power
 	 * management unit which the ftide020 is connected to. In current,
 	 * there are only few PMU supports in u-boot.
 	 * So this function is wait for future enhancement.
 	 */
 	return 100;
 }

 /* Calculate Timing Registers */
 static unsigned int timing_cal(u16 t0, u16 t1, u16 t2, u16 t4)
 {
 	unsigned int val, ahb_ns = 8;
 	u8 TEOC, T1, T2, T4;

 	T1 = (u8) (t1 / ahb_ns);
 	if ((T1 * ahb_ns) == t1)
 		T1--;

 	T2 = (u8) (t2 / ahb_ns);
 	if ((T2 * ahb_ns) == t2)
 		T2--;

 	T4 = (u8) (t4 / ahb_ns);
 	if ((T4 * ahb_ns) == t4)
 		T4--;

 	TEOC = (u8) (t0 / ahb_ns);
 	if ((TEOC * ahb_ns) == t0)
 		TEOC--;

 	TEOC = ((TEOC > (T1 + T2 + T4)) ? (TEOC - (T1 + T2 + T4)) : 0);

 	/*
 	 * Here the fields in data timing registers in PIO mode
 	 * is accessed the same way as command timing registers.
 	 */
 	val =	DT_REG_PIO_T1(T1)	|
 		DT_REG_PIO_T2(T2)	|
 		DT_REG_PIO_T4(T4)	|
 		DT_REG_PIO_TEOC(TEOC);

 	return val;
 }

 /* Set Timing Register */
 static unsigned int set_mode_timing(u8 dev, u8 id, u8 mode)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;
 	u16 t0, t1, t2, t4;
 	u8 tcyc, tcvs, tmli, tenv, tack, trp;
 	unsigned int val, sysclk = 8;

 	if (id >= TATOL_TIMING)
 		return 0;

 	sysclk = ftide_clock_freq();
 	switch (id) {
 	case CMD_TIMING:
 		if (mode < REG_MODE) {
 			t0 = REG_ACCESS_TIMING[REG_T0][mode];
 			t1 = REG_ACCESS_TIMING[REG_T1][mode];
 			t2 = REG_ACCESS_TIMING[REG_T2][mode];
 			t4 = REG_ACCESS_TIMING[REG_T4][mode];

 			val = timing_cal(t0, t1, t2, t4);
 			outl(val, (dev ? &ftide020->ctrd1 : &ftide020->ctrd0));
 			return 1;
 		} else
 			return 0;
 	case PIO_TIMING:
 		if (mode < PIO_MODE) {
 			t0 = PIO_ACCESS_TIMING[PIO_T0][mode];
 			t1 = PIO_ACCESS_TIMING[PIO_T1][mode];
 			t2 = PIO_ACCESS_TIMING[PIO_T2][mode];
 			t4 = PIO_ACCESS_TIMING[PIO_T4][mode];

 			val = timing_cal(t0, t1, t2, t4);

 			outl(val, (dev ? &ftide020->dtrd1 : &ftide020->dtrd0));
 			return 1;
 		} else
 			return 0;
 	case DMA_TIMING:
 		if (mode < UDMA_MODE) {
 			/*
 			 * 0.999 is ceiling
 			 * for tcyc, tcvs, tmli, tenv, trp, tack
 			 */
 			tcyc = (u8) (((UDMA_ACCESS_TIMING[UDMA_TCYC][mode] \
 						* sysclk) + 9990) / 10000);
 			tcvs = (u8) (((UDMA_ACCESS_TIMING[UDMA_TCVS][mode] \
 						* sysclk) + 9990) / 10000);
 			tmli = (u8) (((UDMA_ACCESS_TIMING[UDMA_TMLI][mode] \
 						* sysclk) + 9990) / 10000);
 			tenv = (u8) (((UDMA_ACCESS_TIMING[UDMA_TENV][mode] \
 						* sysclk) + 9990) / 10000);
 			trp  = (u8) (((UDMA_ACCESS_TIMING[UDMA_TRP][mode] \
 						* sysclk) + 9990) / 10000);
 			tack = (u8) (((UDMA_ACCESS_TIMING[UDMA_TACK][mode] \
 						 * sysclk) + 9990) / 10000);

 			val  =	DT_REG_UDMA_TENV((tenv > 0) ? (tenv - 1) : 0) |
 				DT_REG_UDMA_TMLI((tmli > 0) ? (tmli - 1) : 0) |
 				DT_REG_UDMA_TCYC((tcyc > 0) ? (tcyc - 1) : 0) |
 				DT_REG_UDMA_TACK((tack > 0) ? (tack - 1) : 0) |
 				DT_REG_UDMA_TCVS((tcvs > 0) ? (tcvs - 1) : 0) |
 				DT_REG_UDMA_TRP((trp > 0) ? (trp - 1) : 0);

 			outl(val, (dev ? &ftide020->dtrd1 : &ftide020->dtrd0));
 			return 1;
 		} else
 			return 0;
 	default:
 		return 0;
 	}
 }

 static void ftide_read_hwrev(void)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;
 	unsigned int rev;

 	rev = inl(&ftide020->revision);
 }

 static int ftide_controller_probe(void)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;
 	unsigned int bak;

 	bak = inl(&ftide020->ctrd1);

 	/* probing by using shorter setup time */
 	outl(CONFIG_CTRD1_PROBE_T1, &ftide020->ctrd1);
 	if ((inl(&ftide020->ctrd1) & 0xff) != CONFIG_CTRD1_PROBE_T1) {
 		outl(bak, &ftide020->ctrd1);
 		return 0;
 	}

 	/* probing by using longer setup time */
 	outl(CONFIG_CTRD1_PROBE_T2, &ftide020->ctrd1);
 	if ((inl(&ftide020->ctrd1) & 0xff) != CONFIG_CTRD1_PROBE_T2) {
 		outl(bak, &ftide020->ctrd1);
 		return 0;
 	}

 	outl(bak, &ftide020->ctrd1);

 	return 1;
 }

 /* ide_preinit() was migrated from linux driver ide_probe_for_ftide() */
 int ide_preinit(void)
 {
 	static struct ftide020_s *ftide020 = (struct ftide020_s *) FTIDE_BASE;
 	int status;
 	unsigned int val;
 	int i;

 	status = 1;
 	for (i = 0; i < CONFIG_SYS_IDE_MAXBUS; i++)
 		ide_bus_offset[i] = -ATA_STATUS;

 	/* auto-detect IDE controller */
 	if (ftide_controller_probe()) {
 		printf("FTIDE020_S\n");
 	} else {
 		printf("FTIDE020_S ATA controller not found.\n");
 		return API_ENODEV;
 	}

 	/* check HW IP revision */
 	ftide_read_hwrev();

 	/* set FIFO threshold */
 	outl(((WRITE_FIFO - RX_THRESH) << 16) | RX_THRESH, &ftide020->dmatirr);

 	/* set Device_0 PIO_4 timing */
 	set_mode_timing(0, CMD_TIMING, REG_MODE4);
 	set_mode_timing(0, PIO_TIMING, PIO_MODE4);

 	/* set Device_1 PIO_4 timing */
 	set_mode_timing(1, CMD_TIMING, REG_MODE4);
 	set_mode_timing(1, PIO_TIMING, PIO_MODE4);

 	/* from E-bios */
 	/* little endian */
 	outl(0x0, &ftide020->cr);
 	mdelay(10);

 	outl(0x0fff0fff, &ftide020->ahbtr);
 	mdelay(10);

 	/* Enable controller Interrupt */
 	val = inl(&ftide020->cr);

 	/* Enable: IDE IRQ, IDE Terminate ERROR IRQ, AHB Timeout error IRQ */
 	val |= (CONTROL_IIE | CONTROL_TERIE | CONTROL_AERIE);
 	outl(val, &ftide020->cr);

 	status = 0;

 	return status;
 }

 void ide_set_reset(int flag)
 {
 	debug("ide_set_reset()\n");
 	reset_ide_controller();
 	return;
 }
	/*
	* Faraday FTIDE020 ATA Controller (AHB)
	*
	* (C) Copyright 2011 Andes Technology
	* Greentime Hu <greentime@andestech.com>
	* Macpaul Lin <macpaul@andestech.com>
	* Kuo-Wei Chou <kwchou@andestech.com>
	*
	* See file CREDITS for list of people who contributed to this
	* project.
	*
	* 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, write to the Free Software
	* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
	* MA 02111-1307 USA
	*
	*/
	/* ftide020.c - ide support functions for the FTIDE020_S controller */

	#include <config.h>
	#include <common.h>
	#include <ata.h>
	#include <ide.h>
	#include <asm/io.h>
	#include <api_public.h>

	#include "ftide020.h"

	/* base address */
	#define FTIDE_BASE CONFIG_SYS_ATA_BASE_ADDR

	/*
	* data address - The CMD and DATA use the same FIFO in FTIDE020_S
	* FTIDE_DATA = CONFIG_SYS_ATA_BASE_ADDR + CONFIG_SYS_ATA_DATA_OFFSET
	* = &ftide020->rw_fifo
	*/
	#define FTIDE_DATA (&ftide020->rw_fifo)

	/* command and data I/O macros */
	/* 0x0 - DATA FIFO */
	#define WRITE_DATA(x) outl((x), &ftide020->rw_fifo) /* 0x00 */
	#define READ_DATA() inl(&ftide020->rw_fifo) /* 0x00 */
	/* 0x04 - R: Status Reg, W: CMD_FIFO */
	#define WRITE_CMD(x) outl((x), &ftide020->cmd_fifo) /* 0x04 */
	#define READ_STATUS() inl(&ftide020->cmd_fifo) /* 0x04 */

	void ftide_set_device(int cx8, int dev)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;

	WRITE_CMD(SET_DEV_CMD \| IDE_SET_CX8(cx8) \| dev);
	}

	unsigned char ide_read_register(int dev, unsigned int port)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;

	ftide_set_device(0, dev);
	WRITE_CMD(READ_REG_CMD \| IDE_REG_CS_READ(CONFIG_IDE_REG_CS) \|
	IDE_REG_DA_WRITE(port));

	return READ_DATA() & 0xff;
	}

	void ide_write_register(int dev, unsigned int port, unsigned char val)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;

	ftide_set_device(0, dev);
	WRITE_CMD(WRITE_REG_CMD \| IDE_REG_CS_WRITE(CONFIG_IDE_REG_CS) \|
	IDE_REG_DA_WRITE(port) \| val);
	}

	void ide_write_data(int dev, ulong *sect_buf, int words)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;

	ftide_set_device(0, dev);
	WRITE_CMD(WRITE_DATA_CMD \| ((words << 2) - 1));

	/* block write */
	outsl(FTIDE_DATA, sect_buf, words);
	}

	void ide_read_data(int dev, ulong *sect_buf, int words)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;

	ftide_set_device(0, dev);
	WRITE_CMD(READ_DATA_CMD \| ((words << 2) - 1));

	/* block read */
	insl(FTIDE_DATA, sect_buf, words);
	}

	void ftide_dfifo_ready(ulong *time)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;

	while (!(READ_STATUS() & STATUS_RFE)) {
	if (*time-- == 0)
	break;

	udelay(100);
	}
	}

	extern ulong ide_bus_offset[CONFIG_SYS_IDE_MAXBUS];

	/* Reset_IDE_controller */
	static void reset_ide_controller(void)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;
	unsigned int val;

	val = inl(&ftide020->cr);

	val \|= CONTROL_RST;
	outl(val, &ftide020->cr);

	/* wait until reset OK, this is poor HW design */
	mdelay(50);
	val &= ~(CONTROL_RST);
	outl(val, &ftide020->cr);

	mdelay(50);
	val \|= CONTROL_SRST;
	outl(val, &ftide020->cr);

	/* wait until reset OK, this is poor HW design */
	mdelay(50);
	val &= ~(CONTROL_SRST);
	outl(val, &ftide020->cr);

	/* IORDY enable for PIO, for 2 device */
	val \|= (CONTROL_IRE0 \| CONTROL_IRE1);
	outl(val, &ftide020->cr);
	}

	/* IDE clock frequence */
	uint ftide_clock_freq(void)
	{
	/*
	* todo: To aquire dynamic system frequency is dependend on the power
	* management unit which the ftide020 is connected to. In current,
	* there are only few PMU supports in u-boot.
	* So this function is wait for future enhancement.
	*/
	return 100;
	}

	/* Calculate Timing Registers */
	static unsigned int timing_cal(u16 t0, u16 t1, u16 t2, u16 t4)
	{
	unsigned int val, ahb_ns = 8;
	u8 TEOC, T1, T2, T4;

	T1 = (u8) (t1 / ahb_ns);
	if ((T1 * ahb_ns) == t1)
	T1--;

	T2 = (u8) (t2 / ahb_ns);
	if ((T2 * ahb_ns) == t2)
	T2--;

	T4 = (u8) (t4 / ahb_ns);
	if ((T4 * ahb_ns) == t4)
	T4--;

	TEOC = (u8) (t0 / ahb_ns);
	if ((TEOC * ahb_ns) == t0)
	TEOC--;

	TEOC = ((TEOC > (T1 + T2 + T4)) ? (TEOC - (T1 + T2 + T4)) : 0);

	/*
	* Here the fields in data timing registers in PIO mode
	* is accessed the same way as command timing registers.
	*/
	val = DT_REG_PIO_T1(T1) \|
	DT_REG_PIO_T2(T2) \|
	DT_REG_PIO_T4(T4) \|
	DT_REG_PIO_TEOC(TEOC);

	return val;
	}

	/* Set Timing Register */
	static unsigned int set_mode_timing(u8 dev, u8 id, u8 mode)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;
	u16 t0, t1, t2, t4;
	u8 tcyc, tcvs, tmli, tenv, tack, trp;
	unsigned int val, sysclk = 8;

	if (id >= TATOL_TIMING)
	return 0;

	sysclk = ftide_clock_freq();
	switch (id) {
	case CMD_TIMING:
	if (mode < REG_MODE) {
	t0 = REG_ACCESS_TIMING[REG_T0][mode];
	t1 = REG_ACCESS_TIMING[REG_T1][mode];
	t2 = REG_ACCESS_TIMING[REG_T2][mode];
	t4 = REG_ACCESS_TIMING[REG_T4][mode];

	val = timing_cal(t0, t1, t2, t4);
	outl(val, (dev ? &ftide020->ctrd1 : &ftide020->ctrd0));
	return 1;
	} else
	return 0;
	case PIO_TIMING:
	if (mode < PIO_MODE) {
	t0 = PIO_ACCESS_TIMING[PIO_T0][mode];
	t1 = PIO_ACCESS_TIMING[PIO_T1][mode];
	t2 = PIO_ACCESS_TIMING[PIO_T2][mode];
	t4 = PIO_ACCESS_TIMING[PIO_T4][mode];

	val = timing_cal(t0, t1, t2, t4);

	outl(val, (dev ? &ftide020->dtrd1 : &ftide020->dtrd0));
	return 1;
	} else
	return 0;
	case DMA_TIMING:
	if (mode < UDMA_MODE) {
	/*
	* 0.999 is ceiling
	* for tcyc, tcvs, tmli, tenv, trp, tack
	*/
	tcyc = (u8) (((UDMA_ACCESS_TIMING[UDMA_TCYC][mode] \
	* sysclk) + 9990) / 10000);
	tcvs = (u8) (((UDMA_ACCESS_TIMING[UDMA_TCVS][mode] \
	* sysclk) + 9990) / 10000);
	tmli = (u8) (((UDMA_ACCESS_TIMING[UDMA_TMLI][mode] \
	* sysclk) + 9990) / 10000);
	tenv = (u8) (((UDMA_ACCESS_TIMING[UDMA_TENV][mode] \
	* sysclk) + 9990) / 10000);
	trp = (u8) (((UDMA_ACCESS_TIMING[UDMA_TRP][mode] \
	* sysclk) + 9990) / 10000);
	tack = (u8) (((UDMA_ACCESS_TIMING[UDMA_TACK][mode] \
	* sysclk) + 9990) / 10000);

	val = DT_REG_UDMA_TENV((tenv > 0) ? (tenv - 1) : 0) \|
	DT_REG_UDMA_TMLI((tmli > 0) ? (tmli - 1) : 0) \|
	DT_REG_UDMA_TCYC((tcyc > 0) ? (tcyc - 1) : 0) \|
	DT_REG_UDMA_TACK((tack > 0) ? (tack - 1) : 0) \|
	DT_REG_UDMA_TCVS((tcvs > 0) ? (tcvs - 1) : 0) \|
	DT_REG_UDMA_TRP((trp > 0) ? (trp - 1) : 0);

	outl(val, (dev ? &ftide020->dtrd1 : &ftide020->dtrd0));
	return 1;
	} else
	return 0;
	default:
	return 0;
	}
	}

	static void ftide_read_hwrev(void)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;
	unsigned int rev;

	rev = inl(&ftide020->revision);
	}

	static int ftide_controller_probe(void)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;
	unsigned int bak;

	bak = inl(&ftide020->ctrd1);

	/* probing by using shorter setup time */
	outl(CONFIG_CTRD1_PROBE_T1, &ftide020->ctrd1);
	if ((inl(&ftide020->ctrd1) & 0xff) != CONFIG_CTRD1_PROBE_T1) {
	outl(bak, &ftide020->ctrd1);
	return 0;
	}

	/* probing by using longer setup time */
	outl(CONFIG_CTRD1_PROBE_T2, &ftide020->ctrd1);
	if ((inl(&ftide020->ctrd1) & 0xff) != CONFIG_CTRD1_PROBE_T2) {
	outl(bak, &ftide020->ctrd1);
	return 0;
	}

	outl(bak, &ftide020->ctrd1);

	return 1;
	}

	/* ide_preinit() was migrated from linux driver ide_probe_for_ftide() */
	int ide_preinit(void)
	{
	static struct ftide020_s ftide020 = (struct ftide020_s ) FTIDE_BASE;
	int status;
	unsigned int val;
	int i;

	status = 1;
	for (i = 0; i < CONFIG_SYS_IDE_MAXBUS; i++)
	ide_bus_offset[i] = -ATA_STATUS;

	/* auto-detect IDE controller */
	if (ftide_controller_probe()) {
	printf("FTIDE020_S\n");
	} else {
	printf("FTIDE020_S ATA controller not found.\n");
	return API_ENODEV;
	}

	/* check HW IP revision */
	ftide_read_hwrev();

	/* set FIFO threshold */
	outl(((WRITE_FIFO - RX_THRESH) << 16) \| RX_THRESH, &ftide020->dmatirr);

	/* set Device_0 PIO_4 timing */
	set_mode_timing(0, CMD_TIMING, REG_MODE4);
	set_mode_timing(0, PIO_TIMING, PIO_MODE4);

	/* set Device_1 PIO_4 timing */
	set_mode_timing(1, CMD_TIMING, REG_MODE4);
	set_mode_timing(1, PIO_TIMING, PIO_MODE4);

	/* from E-bios */
	/* little endian */
	outl(0x0, &ftide020->cr);
	mdelay(10);

	outl(0x0fff0fff, &ftide020->ahbtr);
	mdelay(10);

	/* Enable controller Interrupt */
	val = inl(&ftide020->cr);

	/* Enable: IDE IRQ, IDE Terminate ERROR IRQ, AHB Timeout error IRQ */
	val \|= (CONTROL_IIE \| CONTROL_TERIE \| CONTROL_AERIE);
	outl(val, &ftide020->cr);

	status = 0;

	return status;
	}

	void ide_set_reset(int flag)
	{
	debug("ide_set_reset()\n");
	reset_ide_controller();
	return;
	}