u-boot/drivers/spi/fsl_qspi.c

// SPDX-License-Identifier: GPL-2.0+

/*
 * Freescale QuadSPI driver.
 *
 * Copyright (C) 2013 Freescale Semiconductor, Inc.
 * Copyright (C) 2018 Bootlin
 * Copyright (C) 2018 exceet electronics GmbH
 * Copyright (C) 2018 Kontron Electronics GmbH
 * Copyright 2019-2020 NXP
 *
 * This driver is a ported version of Linux Freescale QSPI driver taken from
 * v5.5-rc1 tag having following information.
 *
 * Transition to SPI MEM interface:
 * Authors:
 *     Boris Brezillon <bbrezillon@kernel.org>
 *     Frieder Schrempf <frieder.schrempf@kontron.de>
 *     Yogesh Gaur <yogeshnarayan.gaur@nxp.com>
 *     Suresh Gupta <suresh.gupta@nxp.com>
 *
 * Based on the original fsl-quadspi.c spi-nor driver.
 * Transition to spi-mem in spi-fsl-qspi.c
 */

#include <common.h>
#include <log.h>
#include <asm/io.h>
#include <linux/bitops.h>
#include <linux/delay.h>
#include <linux/libfdt.h>
#include <linux/sizes.h>
#include <linux/iopoll.h>
#include <dm.h>
#include <linux/iopoll.h>
#include <linux/sizes.h>
#include <linux/err.h>
#include <spi.h>
#include <spi-mem.h>

DECLARE_GLOBAL_DATA_PTR;

/*
 * The driver only uses one single LUT entry, that is updated on
 * each call of exec_op(). Index 0 is preset at boot with a basic
 * read operation, so let's use the last entry (15).
 */
#define	SEQID_LUT			15

/* Registers used by the driver */
#define QUADSPI_MCR			0x00
#define QUADSPI_MCR_RESERVED_MASK	GENMASK(19, 16)
#define QUADSPI_MCR_MDIS_MASK		BIT(14)
#define QUADSPI_MCR_CLR_TXF_MASK	BIT(11)
#define QUADSPI_MCR_CLR_RXF_MASK	BIT(10)
#define QUADSPI_MCR_DDR_EN_MASK		BIT(7)
#define QUADSPI_MCR_END_CFG_MASK	GENMASK(3, 2)
#define QUADSPI_MCR_SWRSTHD_MASK	BIT(1)
#define QUADSPI_MCR_SWRSTSD_MASK	BIT(0)

#define QUADSPI_IPCR			0x08
#define QUADSPI_IPCR_SEQID(x)		((x) << 24)
#define QUADSPI_FLSHCR			0x0c
#define QUADSPI_FLSHCR_TCSS_MASK	GENMASK(3, 0)
#define QUADSPI_FLSHCR_TCSH_MASK	GENMASK(11, 8)
#define QUADSPI_FLSHCR_TDH_MASK		GENMASK(17, 16)

#define QUADSPI_BUF3CR			0x1c
#define QUADSPI_BUF3CR_ALLMST_MASK	BIT(31)
#define QUADSPI_BUF3CR_ADATSZ(x)	((x) << 8)
#define QUADSPI_BUF3CR_ADATSZ_MASK	GENMASK(15, 8)

#define QUADSPI_BFGENCR			0x20
#define QUADSPI_BFGENCR_SEQID(x)	((x) << 12)

#define QUADSPI_BUF0IND			0x30
#define QUADSPI_BUF1IND			0x34
#define QUADSPI_BUF2IND			0x38
#define QUADSPI_SFAR			0x100

#define QUADSPI_SMPR			0x108
#define QUADSPI_SMPR_DDRSMP_MASK	GENMASK(18, 16)
#define QUADSPI_SMPR_FSDLY_MASK		BIT(6)
#define QUADSPI_SMPR_FSPHS_MASK		BIT(5)
#define QUADSPI_SMPR_HSENA_MASK		BIT(0)

#define QUADSPI_RBCT			0x110
#define QUADSPI_RBCT_WMRK_MASK		GENMASK(4, 0)
#define QUADSPI_RBCT_RXBRD_USEIPS	BIT(8)

#define QUADSPI_TBDR			0x154

#define QUADSPI_SR			0x15c
#define QUADSPI_SR_IP_ACC_MASK		BIT(1)
#define QUADSPI_SR_AHB_ACC_MASK		BIT(2)

#define QUADSPI_FR			0x160
#define QUADSPI_FR_TFF_MASK		BIT(0)

#define QUADSPI_RSER			0x164
#define QUADSPI_RSER_TFIE		BIT(0)

#define QUADSPI_SPTRCLR			0x16c
#define QUADSPI_SPTRCLR_IPPTRC		BIT(8)
#define QUADSPI_SPTRCLR_BFPTRC		BIT(0)

#define QUADSPI_SFA1AD			0x180
#define QUADSPI_SFA2AD			0x184
#define QUADSPI_SFB1AD			0x188
#define QUADSPI_SFB2AD			0x18c
#define QUADSPI_RBDR(x)			(0x200 + ((x) * 4))

#define QUADSPI_LUTKEY			0x300
#define QUADSPI_LUTKEY_VALUE		0x5AF05AF0

#define QUADSPI_LCKCR			0x304
#define QUADSPI_LCKER_LOCK		BIT(0)
#define QUADSPI_LCKER_UNLOCK		BIT(1)

#define QUADSPI_LUT_BASE		0x310
#define QUADSPI_LUT_OFFSET		(SEQID_LUT * 4 * 4)
#define QUADSPI_LUT_REG(idx) \
	(QUADSPI_LUT_BASE + QUADSPI_LUT_OFFSET + (idx) * 4)

/* Instruction set for the LUT register */
#define LUT_STOP		0
#define LUT_CMD			1
#define LUT_ADDR		2
#define LUT_DUMMY		3
#define LUT_MODE		4
#define LUT_MODE2		5
#define LUT_MODE4		6
#define LUT_FSL_READ		7
#define LUT_FSL_WRITE		8
#define LUT_JMP_ON_CS		9
#define LUT_ADDR_DDR		10
#define LUT_MODE_DDR		11
#define LUT_MODE2_DDR		12
#define LUT_MODE4_DDR		13
#define LUT_FSL_READ_DDR	14
#define LUT_FSL_WRITE_DDR	15
#define LUT_DATA_LEARN		16

/*
 * The PAD definitions for LUT register.
 *
 * The pad stands for the number of IO lines [0:3].
 * For example, the quad read needs four IO lines,
 * so you should use LUT_PAD(4).
 */
#define LUT_PAD(x) (fls(x) - 1)

/*
 * Macro for constructing the LUT entries with the following
 * register layout:
 *
 *  ---------------------------------------------------
 *  | INSTR1 | PAD1 | OPRND1 | INSTR0 | PAD0 | OPRND0 |
 *  ---------------------------------------------------
 */
#define LUT_DEF(idx, ins, pad, opr)					\
	((((ins) << 10) | ((pad) << 8) | (opr)) << (((idx) % 2) * 16))

/* Controller needs driver to swap endianness */
#define QUADSPI_QUIRK_SWAP_ENDIAN	BIT(0)

/* Controller needs 4x internal clock */
#define QUADSPI_QUIRK_4X_INT_CLK	BIT(1)

/*
 * TKT253890, the controller needs the driver to fill the txfifo with
 * 16 bytes at least to trigger a data transfer, even though the extra
 * data won't be transferred.
 */
#define QUADSPI_QUIRK_TKT253890		BIT(2)

/* TKT245618, the controller cannot wake up from wait mode */
#define QUADSPI_QUIRK_TKT245618		BIT(3)

/*
 * Controller adds QSPI_AMBA_BASE (base address of the mapped memory)
 * internally. No need to add it when setting SFXXAD and SFAR registers
 */
#define QUADSPI_QUIRK_BASE_INTERNAL	BIT(4)

/*
 * Controller uses TDH bits in register QUADSPI_FLSHCR.
 * They need to be set in accordance with the DDR/SDR mode.
 */
#define QUADSPI_QUIRK_USE_TDH_SETTING	BIT(5)

struct fsl_qspi_devtype_data {
	unsigned int rxfifo;
	unsigned int txfifo;
	unsigned int ahb_buf_size;
	unsigned int quirks;
	bool little_endian;
};

static const struct fsl_qspi_devtype_data vybrid_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_64,
	.ahb_buf_size = SZ_1K,
	.quirks = QUADSPI_QUIRK_SWAP_ENDIAN,
	.little_endian = true,
};

static const struct fsl_qspi_devtype_data imx6sx_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_512,
	.ahb_buf_size = SZ_1K,
	.quirks = QUADSPI_QUIRK_4X_INT_CLK | QUADSPI_QUIRK_TKT245618,
	.little_endian = true,
};

static const struct fsl_qspi_devtype_data imx7d_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_512,
	.ahb_buf_size = SZ_1K,
	.quirks = QUADSPI_QUIRK_TKT253890 | QUADSPI_QUIRK_4X_INT_CLK |
		  QUADSPI_QUIRK_USE_TDH_SETTING,
	.little_endian = true,
};

static const struct fsl_qspi_devtype_data imx6ul_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_512,
	.ahb_buf_size = SZ_1K,
	.quirks = QUADSPI_QUIRK_TKT253890 | QUADSPI_QUIRK_4X_INT_CLK |
		  QUADSPI_QUIRK_USE_TDH_SETTING,
	.little_endian = true,
};

static const struct fsl_qspi_devtype_data ls1021a_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_64,
	.ahb_buf_size = SZ_1K,
	.quirks = 0,
	.little_endian = false,
};

static const struct fsl_qspi_devtype_data ls1088a_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_128,
	.ahb_buf_size = SZ_1K,
	.quirks = QUADSPI_QUIRK_TKT253890,
	.little_endian = true,
};

static const struct fsl_qspi_devtype_data ls2080a_data = {
	.rxfifo = SZ_128,
	.txfifo = SZ_64,
	.ahb_buf_size = SZ_1K,
	.quirks = QUADSPI_QUIRK_TKT253890 | QUADSPI_QUIRK_BASE_INTERNAL,
	.little_endian = true,
};

struct fsl_qspi {
	struct udevice *dev;
	void __iomem *iobase;
	void __iomem *ahb_addr;
	u32 memmap_phy;
	const struct fsl_qspi_devtype_data *devtype_data;
	int selected;
};

static inline int needs_swap_endian(struct fsl_qspi *q)
{
	return q->devtype_data->quirks & QUADSPI_QUIRK_SWAP_ENDIAN;
}

static inline int needs_4x_clock(struct fsl_qspi *q)
{
	return q->devtype_data->quirks & QUADSPI_QUIRK_4X_INT_CLK;
}

static inline int needs_fill_txfifo(struct fsl_qspi *q)
{
	return q->devtype_data->quirks & QUADSPI_QUIRK_TKT253890;
}

static inline int needs_wakeup_wait_mode(struct fsl_qspi *q)
{
	return q->devtype_data->quirks & QUADSPI_QUIRK_TKT245618;
}

static inline int needs_amba_base_offset(struct fsl_qspi *q)
{
	return !(q->devtype_data->quirks & QUADSPI_QUIRK_BASE_INTERNAL);
}

static inline int needs_tdh_setting(struct fsl_qspi *q)
{
	return q->devtype_data->quirks & QUADSPI_QUIRK_USE_TDH_SETTING;
}

/*
 * An IC bug makes it necessary to rearrange the 32-bit data.
 * Later chips, such as IMX6SLX, have fixed this bug.
 */
static inline u32 fsl_qspi_endian_xchg(struct fsl_qspi *q, u32 a)
{
	return needs_swap_endian(q) ? __swab32(a) : a;
}

/*
 * R/W functions for big- or little-endian registers:
 * The QSPI controller's endianness is independent of
 * the CPU core's endianness. So far, although the CPU
 * core is little-endian the QSPI controller can use
 * big-endian or little-endian.
 */
static void qspi_writel(struct fsl_qspi *q, u32 val, void __iomem *addr)
{
	if (q->devtype_data->little_endian)
		out_le32(addr, val);
	else
		out_be32(addr, val);
}

static u32 qspi_readl(struct fsl_qspi *q, void __iomem *addr)
{
	if (q->devtype_data->little_endian)
		return in_le32(addr);

	return in_be32(addr);
}

static int fsl_qspi_check_buswidth(struct fsl_qspi *q, u8 width)
{
	switch (width) {
	case 1:
	case 2:
	case 4:
		return 0;
	}

	return -ENOTSUPP;
}

static bool fsl_qspi_supports_op(struct spi_slave *slave,
				 const struct spi_mem_op *op)
{
	struct fsl_qspi *q = dev_get_priv(slave->dev->parent);
	int ret;

	ret = fsl_qspi_check_buswidth(q, op->cmd.buswidth);

	if (op->addr.nbytes)
		ret |= fsl_qspi_check_buswidth(q, op->addr.buswidth);

	if (op->dummy.nbytes)
		ret |= fsl_qspi_check_buswidth(q, op->dummy.buswidth);

	if (op->data.nbytes)
		ret |= fsl_qspi_check_buswidth(q, op->data.buswidth);

	if (ret)
		return false;

	/*
	 * The number of instructions needed for the op, needs
	 * to fit into a single LUT entry.
	 */
	if (op->addr.nbytes +
	   (op->dummy.nbytes ? 1 : 0) +
	   (op->data.nbytes ? 1 : 0) > 6)
		return false;

	/* Max 64 dummy clock cycles supported */
	if (op->dummy.nbytes &&
	    (op->dummy.nbytes * 8 / op->dummy.buswidth > 64))
		return false;

	/* Max data length, check controller limits and alignment */
	if (op->data.dir == SPI_MEM_DATA_IN &&
	    (op->data.nbytes > q->devtype_data->ahb_buf_size ||
	     (op->data.nbytes > q->devtype_data->rxfifo - 4 &&
	      !IS_ALIGNED(op->data.nbytes, 8))))
		return false;

	if (op->data.dir == SPI_MEM_DATA_OUT &&
	    op->data.nbytes > q->devtype_data->txfifo)
		return false;

	return true;
}

static void fsl_qspi_prepare_lut(struct fsl_qspi *q,
				 const struct spi_mem_op *op)
{
	void __iomem *base = q->iobase;
	u32 lutval[4] = {};
	int lutidx = 1, i;

	lutval[0] |= LUT_DEF(0, LUT_CMD, LUT_PAD(op->cmd.buswidth),
			     op->cmd.opcode);

	/*
	 * For some unknown reason, using LUT_ADDR doesn't work in some
	 * cases (at least with only one byte long addresses), so
	 * let's use LUT_MODE to write the address bytes one by one
	 */
	for (i = 0; i < op->addr.nbytes; i++) {
		u8 addrbyte = op->addr.val >> (8 * (op->addr.nbytes - i - 1));

		lutval[lutidx / 2] |= LUT_DEF(lutidx, LUT_MODE,
					      LUT_PAD(op->addr.buswidth),
					      addrbyte);
		lutidx++;
	}

	if (op->dummy.nbytes) {
		lutval[lutidx / 2] |= LUT_DEF(lutidx, LUT_DUMMY,
					      LUT_PAD(op->dummy.buswidth),
					      op->dummy.nbytes * 8 /
					      op->dummy.buswidth);
		lutidx++;
	}

	if (op->data.nbytes) {
		lutval[lutidx / 2] |= LUT_DEF(lutidx,
					      op->data.dir == SPI_MEM_DATA_IN ?
					      LUT_FSL_READ : LUT_FSL_WRITE,
					      LUT_PAD(op->data.buswidth),
					      0);
		lutidx++;
	}

	lutval[lutidx / 2] |= LUT_DEF(lutidx, LUT_STOP, 0, 0);

	/* unlock LUT */
	qspi_writel(q, QUADSPI_LUTKEY_VALUE, q->iobase + QUADSPI_LUTKEY);
	qspi_writel(q, QUADSPI_LCKER_UNLOCK, q->iobase + QUADSPI_LCKCR);

	dev_dbg(q->dev, "CMD[%x] lutval[0:%x \t 1:%x \t 2:%x \t 3:%x]\n",
		op->cmd.opcode, lutval[0], lutval[1], lutval[2], lutval[3]);

	/* fill LUT */
	for (i = 0; i < ARRAY_SIZE(lutval); i++)
		qspi_writel(q, lutval[i], base + QUADSPI_LUT_REG(i));

	/* lock LUT */
	qspi_writel(q, QUADSPI_LUTKEY_VALUE, q->iobase + QUADSPI_LUTKEY);
	qspi_writel(q, QUADSPI_LCKER_LOCK, q->iobase + QUADSPI_LCKCR);
}

/*
 * If we have changed the content of the flash by writing or erasing, or if we
 * read from flash with a different offset into the page buffer, we need to
 * invalidate the AHB buffer. If we do not do so, we may read out the wrong
 * data. The spec tells us reset the AHB domain and Serial Flash domain at
 * the same time.
 */
static void fsl_qspi_invalidate(struct fsl_qspi *q)
{
	u32 reg;

	reg = qspi_readl(q, q->iobase + QUADSPI_MCR);
	reg |= QUADSPI_MCR_SWRSTHD_MASK | QUADSPI_MCR_SWRSTSD_MASK;
	qspi_writel(q, reg, q->iobase + QUADSPI_MCR);

	/*
	 * The minimum delay : 1 AHB + 2 SFCK clocks.
	 * Delay 1 us is enough.
	 */
	udelay(1);

	reg &= ~(QUADSPI_MCR_SWRSTHD_MASK | QUADSPI_MCR_SWRSTSD_MASK);
	qspi_writel(q, reg, q->iobase + QUADSPI_MCR);
}

static void fsl_qspi_select_mem(struct fsl_qspi *q, struct spi_slave *slave)
{
	struct dm_spi_slave_platdata *plat =
		dev_get_parent_platdata(slave->dev);

	if (q->selected == plat->cs)
		return;

	q->selected = plat->cs;
	fsl_qspi_invalidate(q);
}

static void fsl_qspi_read_ahb(struct fsl_qspi *q, const struct spi_mem_op *op)
{
	memcpy_fromio(op->data.buf.in,
		      q->ahb_addr + q->selected * q->devtype_data->ahb_buf_size,
		      op->data.nbytes);
}

static void fsl_qspi_fill_txfifo(struct fsl_qspi *q,
				 const struct spi_mem_op *op)
{
	void __iomem *base = q->iobase;
	int i;
	u32 val;

	for (i = 0; i < ALIGN_DOWN(op->data.nbytes, 4); i += 4) {
		memcpy(&val, op->data.buf.out + i, 4);
		val = fsl_qspi_endian_xchg(q, val);
		qspi_writel(q, val, base + QUADSPI_TBDR);
	}

	if (i < op->data.nbytes) {
		memcpy(&val, op->data.buf.out + i, op->data.nbytes - i);
		val = fsl_qspi_endian_xchg(q, val);
		qspi_writel(q, val, base + QUADSPI_TBDR);
	}

	if (needs_fill_txfifo(q)) {
		for (i = op->data.nbytes; i < 16; i += 4)
			qspi_writel(q, 0, base + QUADSPI_TBDR);
	}
}

static void fsl_qspi_read_rxfifo(struct fsl_qspi *q,
				 const struct spi_mem_op *op)
{
	void __iomem *base = q->iobase;
	int i;
	u8 *buf = op->data.buf.in;
	u32 val;

	for (i = 0; i < ALIGN_DOWN(op->data.nbytes, 4); i += 4) {
		val = qspi_readl(q, base + QUADSPI_RBDR(i / 4));
		val = fsl_qspi_endian_xchg(q, val);
		memcpy(buf + i, &val, 4);
	}

	if (i < op->data.nbytes) {
		val = qspi_readl(q, base + QUADSPI_RBDR(i / 4));
		val = fsl_qspi_endian_xchg(q, val);
		memcpy(buf + i, &val, op->data.nbytes - i);
	}
}

static int fsl_qspi_readl_poll_tout(struct fsl_qspi *q, void __iomem *base,
				    u32 mask, u32 delay_us, u32 timeout_us)
{
	u32 reg;

	if (!q->devtype_data->little_endian)
		mask = (u32)cpu_to_be32(mask);

	return readl_poll_timeout(base, reg, !(reg & mask), timeout_us);
}

static int fsl_qspi_do_op(struct fsl_qspi *q, const struct spi_mem_op *op)
{
	void __iomem *base = q->iobase;
	int err = 0;

	/*
	 * Always start the sequence at the same index since we update
	 * the LUT at each exec_op() call. And also specify the DATA
	 * length, since it's has not been specified in the LUT.
	 */
	qspi_writel(q, op->data.nbytes | QUADSPI_IPCR_SEQID(SEQID_LUT),
		    base + QUADSPI_IPCR);

	/* wait for the controller being ready */
	err = fsl_qspi_readl_poll_tout(q, base + QUADSPI_SR,
				       (QUADSPI_SR_IP_ACC_MASK |
					QUADSPI_SR_AHB_ACC_MASK),
					10, 1000);

	if (!err && op->data.nbytes && op->data.dir == SPI_MEM_DATA_IN)
		fsl_qspi_read_rxfifo(q, op);

	return err;
}

static int fsl_qspi_exec_op(struct spi_slave *slave,
			    const struct spi_mem_op *op)
{
	struct fsl_qspi *q = dev_get_priv(slave->dev->parent);
	void __iomem *base = q->iobase;
	u32 addr_offset = 0;
	int err = 0;

	/* wait for the controller being ready */
	fsl_qspi_readl_poll_tout(q, base + QUADSPI_SR, (QUADSPI_SR_IP_ACC_MASK |
				 QUADSPI_SR_AHB_ACC_MASK), 10, 1000);

	fsl_qspi_select_mem(q, slave);

	if (needs_amba_base_offset(q))
		addr_offset = q->memmap_phy;

	qspi_writel(q,
		    q->selected * q->devtype_data->ahb_buf_size + addr_offset,
		    base + QUADSPI_SFAR);

	qspi_writel(q, qspi_readl(q, base + QUADSPI_MCR) |
		    QUADSPI_MCR_CLR_RXF_MASK | QUADSPI_MCR_CLR_TXF_MASK,
		    base + QUADSPI_MCR);

	qspi_writel(q, QUADSPI_SPTRCLR_BFPTRC | QUADSPI_SPTRCLR_IPPTRC,
		    base + QUADSPI_SPTRCLR);

	fsl_qspi_prepare_lut(q, op);

	/*
	 * If we have large chunks of data, we read them through the AHB bus
	 * by accessing the mapped memory. In all other cases we use
	 * IP commands to access the flash.
	 */
	if (op->data.nbytes > (q->devtype_data->rxfifo - 4) &&
	    op->data.dir == SPI_MEM_DATA_IN) {
		fsl_qspi_read_ahb(q, op);
	} else {
		qspi_writel(q, QUADSPI_RBCT_WMRK_MASK |
			    QUADSPI_RBCT_RXBRD_USEIPS, base + QUADSPI_RBCT);

		if (op->data.nbytes && op->data.dir == SPI_MEM_DATA_OUT)
			fsl_qspi_fill_txfifo(q, op);

		err = fsl_qspi_do_op(q, op);
	}

	/* Invalidate the data in the AHB buffer. */
	fsl_qspi_invalidate(q);

	return err;
}

static int fsl_qspi_adjust_op_size(struct spi_slave *slave,
				   struct spi_mem_op *op)
{
	struct fsl_qspi *q = dev_get_priv(slave->dev->parent);

	if (op->data.dir == SPI_MEM_DATA_OUT) {
		if (op->data.nbytes > q->devtype_data->txfifo)
			op->data.nbytes = q->devtype_data->txfifo;
	} else {
		if (op->data.nbytes > q->devtype_data->ahb_buf_size)
			op->data.nbytes = q->devtype_data->ahb_buf_size;
		else if (op->data.nbytes > (q->devtype_data->rxfifo - 4))
			op->data.nbytes = ALIGN_DOWN(op->data.nbytes, 8);
	}

	return 0;
}

static int fsl_qspi_default_setup(struct fsl_qspi *q)
{
	void __iomem *base = q->iobase;
	u32 reg, addr_offset = 0;

	/* Reset the module */
	qspi_writel(q, QUADSPI_MCR_SWRSTSD_MASK | QUADSPI_MCR_SWRSTHD_MASK,
		    base + QUADSPI_MCR);
	udelay(1);

	/* Disable the module */
	qspi_writel(q, QUADSPI_MCR_MDIS_MASK | QUADSPI_MCR_RESERVED_MASK,
		    base + QUADSPI_MCR);

	/*
	 * Previous boot stages (BootROM, bootloader) might have used DDR
	 * mode and did not clear the TDH bits. As we currently use SDR mode
	 * only, clear the TDH bits if necessary.
	 */
	if (needs_tdh_setting(q))
		qspi_writel(q, qspi_readl(q, base + QUADSPI_FLSHCR) &
			    ~QUADSPI_FLSHCR_TDH_MASK,
			    base + QUADSPI_FLSHCR);

	reg = qspi_readl(q, base + QUADSPI_SMPR);
	qspi_writel(q, reg & ~(QUADSPI_SMPR_FSDLY_MASK
			| QUADSPI_SMPR_FSPHS_MASK
			| QUADSPI_SMPR_HSENA_MASK
			| QUADSPI_SMPR_DDRSMP_MASK), base + QUADSPI_SMPR);

	/* We only use the buffer3 for AHB read */
	qspi_writel(q, 0, base + QUADSPI_BUF0IND);
	qspi_writel(q, 0, base + QUADSPI_BUF1IND);
	qspi_writel(q, 0, base + QUADSPI_BUF2IND);

	qspi_writel(q, QUADSPI_BFGENCR_SEQID(SEQID_LUT),
		    q->iobase + QUADSPI_BFGENCR);
	qspi_writel(q, QUADSPI_RBCT_WMRK_MASK, base + QUADSPI_RBCT);
	qspi_writel(q, QUADSPI_BUF3CR_ALLMST_MASK |
		    QUADSPI_BUF3CR_ADATSZ(q->devtype_data->ahb_buf_size / 8),
		    base + QUADSPI_BUF3CR);

	if (needs_amba_base_offset(q))
		addr_offset = q->memmap_phy;

	/*
	 * In HW there can be a maximum of four chips on two buses with
	 * two chip selects on each bus. We use four chip selects in SW
	 * to differentiate between the four chips.
	 * We use ahb_buf_size for each chip and set SFA1AD, SFA2AD, SFB1AD,
	 * SFB2AD accordingly.
	 */
	qspi_writel(q, q->devtype_data->ahb_buf_size + addr_offset,
		    base + QUADSPI_SFA1AD);
	qspi_writel(q, q->devtype_data->ahb_buf_size * 2 + addr_offset,
		    base + QUADSPI_SFA2AD);
	qspi_writel(q, q->devtype_data->ahb_buf_size * 3 + addr_offset,
		    base + QUADSPI_SFB1AD);
	qspi_writel(q, q->devtype_data->ahb_buf_size * 4 + addr_offset,
		    base + QUADSPI_SFB2AD);

	q->selected = -1;

	/* Enable the module */
	qspi_writel(q, QUADSPI_MCR_RESERVED_MASK | QUADSPI_MCR_END_CFG_MASK,
		    base + QUADSPI_MCR);
	return 0;
}

static const struct spi_controller_mem_ops fsl_qspi_mem_ops = {
	.adjust_op_size = fsl_qspi_adjust_op_size,
	.supports_op = fsl_qspi_supports_op,
	.exec_op = fsl_qspi_exec_op,
};

static int fsl_qspi_probe(struct udevice *bus)
{
	struct dm_spi_bus *dm_bus = bus->uclass_priv;
	struct fsl_qspi *q = dev_get_priv(bus);
	const void *blob = gd->fdt_blob;
	int node = dev_of_offset(bus);
	struct fdt_resource res;
	int ret;

	q->dev = bus;
	q->devtype_data = (struct fsl_qspi_devtype_data *)
			   dev_get_driver_data(bus);

	/* find the resources */
	ret = fdt_get_named_resource(blob, node, "reg", "reg-names", "QuadSPI",
				     &res);
	if (ret) {
		dev_err(bus, "Can't get regs base addresses(ret = %d)!\n", ret);
		return -ENOMEM;
	}

	q->iobase = map_physmem(res.start, res.end - res.start, MAP_NOCACHE);

	ret = fdt_get_named_resource(blob, node, "reg", "reg-names",
				     "QuadSPI-memory", &res);
	if (ret) {
		dev_err(bus, "Can't get AMBA base addresses(ret = %d)!\n", ret);
		return -ENOMEM;
	}

	q->ahb_addr = map_physmem(res.start, res.end - res.start, MAP_NOCACHE);
	q->memmap_phy = res.start;

	dm_bus->max_hz = fdtdec_get_int(blob, node, "spi-max-frequency",
					66000000);

	fsl_qspi_default_setup(q);

	return 0;
}

static int fsl_qspi_xfer(struct udevice *dev, unsigned int bitlen,
			 const void *dout, void *din, unsigned long flags)
{
	return 0;
}

static int fsl_qspi_claim_bus(struct udevice *dev)
{
	return 0;
}

static int fsl_qspi_release_bus(struct udevice *dev)
{
	return 0;
}

static int fsl_qspi_set_speed(struct udevice *bus, uint speed)
{
	return 0;
}

static int fsl_qspi_set_mode(struct udevice *bus, uint mode)
{
	return 0;
}

static const struct dm_spi_ops fsl_qspi_ops = {
	.claim_bus	= fsl_qspi_claim_bus,
	.release_bus	= fsl_qspi_release_bus,
	.xfer		= fsl_qspi_xfer,
	.set_speed	= fsl_qspi_set_speed,
	.set_mode	= fsl_qspi_set_mode,
	.mem_ops	= &fsl_qspi_mem_ops,
};

static const struct udevice_id fsl_qspi_ids[] = {
	{ .compatible = "fsl,vf610-qspi", .data = (ulong)&vybrid_data, },
	{ .compatible = "fsl,imx6sx-qspi", .data = (ulong)&imx6sx_data, },
	{ .compatible = "fsl,imx6ul-qspi", .data = (ulong)&imx6ul_data, },
	{ .compatible = "fsl,imx7d-qspi", .data = (ulong)&imx7d_data, },
	{ .compatible = "fsl,ls1021a-qspi", .data = (ulong)&ls1021a_data, },
	{ .compatible = "fsl,ls1088a-qspi", .data = (ulong)&ls1088a_data, },
	{ .compatible = "fsl,ls2080a-qspi", .data = (ulong)&ls2080a_data, },
	{ }
};

U_BOOT_DRIVER(fsl_qspi) = {
	.name	= "fsl_qspi",
	.id	= UCLASS_SPI,
	.of_match = fsl_qspi_ids,
	.ops	= &fsl_qspi_ops,
	.priv_auto_alloc_size = sizeof(struct fsl_qspi),
	.probe	= fsl_qspi_probe,
};