drivers/base/regmap/regmap-spi-avmm.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 //
 // Register map access API - SPI AVMM support
 //
 // Copyright (C) 2018-2020 Intel Corporation. All rights reserved.

 #include <linux/module.h>
 #include <linux/regmap.h>
 #include <linux/spi/spi.h>

 /*
  * This driver implements the regmap operations for a generic SPI
  * master to access the registers of the spi slave chip which has an
  * Avalone bus in it.
  *
  * The "SPI slave to Avalon Master Bridge" (spi-avmm) IP should be integrated
  * in the spi slave chip. The IP acts as a bridge to convert encoded streams of
  * bytes from the host to the internal register read/write on Avalon bus. In
  * order to issue register access requests to the slave chip, the host should
  * send formatted bytes that conform to the transfer protocol.
  * The transfer protocol contains 3 layers: transaction layer, packet layer
  * and physical layer.
  *
  * Reference Documents could be found at:
  * https://www.intel.com/content/www/us/en/programmable/documentation/sfo1400787952932.html
  *
  * Chapter "SPI Slave/JTAG to Avalon Master Bridge Cores" is a general
  * introduction to the protocol.
  *
  * Chapter "Avalon Packets to Transactions Converter Core" describes
  * the transaction layer.
  *
  * Chapter "Avalon-ST Bytes to Packets and Packets to Bytes Converter Cores"
  * describes the packet layer.
  *
  * Chapter "Avalon-ST Serial Peripheral Interface Core" describes the
  * physical layer.
  *
  *
  * When host issues a regmap read/write, the driver will transform the request
  * to byte stream layer by layer. It formats the register addr, value and
  * length to the transaction layer request, then converts the request to packet
  * layer bytes stream and then to physical layer bytes stream. Finally the
  * driver sends the formatted byte stream over SPI bus to the slave chip.
  *
  * The spi-avmm IP on the slave chip decodes the byte stream and initiates
  * register read/write on its internal Avalon bus, and then encodes the
  * response to byte stream and sends back to host.
  *
  * The driver receives the byte stream, reverses the 3 layers transformation,
  * and finally gets the response value (read out data for register read,
  * successful written size for register write).
  */

 #define PKT_SOP			0x7a
 #define PKT_EOP			0x7b
 #define PKT_CHANNEL		0x7c
 #define PKT_ESC			0x7d

 #define PHY_IDLE		0x4a
 #define PHY_ESC			0x4d

 #define TRANS_CODE_WRITE	0x0
 #define TRANS_CODE_SEQ_WRITE	0x4
 #define TRANS_CODE_READ		0x10
 #define TRANS_CODE_SEQ_READ	0x14
 #define TRANS_CODE_NO_TRANS	0x7f

 #define SPI_AVMM_XFER_TIMEOUT	(msecs_to_jiffies(200))

 /* slave's register addr is 32 bits */
 #define SPI_AVMM_REG_SIZE		4UL
 /* slave's register value is 32 bits */
 #define SPI_AVMM_VAL_SIZE		4UL

 /*
  * max rx size could be larger. But considering the buffer consuming,
  * it is proper that we limit 1KB xfer at max.
  */
 #define MAX_READ_CNT		256UL
 #define MAX_WRITE_CNT		1UL

 struct trans_req_header {
 	u8 code;
 	u8 rsvd;
 	__be16 size;
 	__be32 addr;
 } __packed;

 struct trans_resp_header {
 	u8 r_code;
 	u8 rsvd;
 	__be16 size;
 } __packed;

 #define TRANS_REQ_HD_SIZE	(sizeof(struct trans_req_header))
 #define TRANS_RESP_HD_SIZE	(sizeof(struct trans_resp_header))

 /*
  * In transaction layer,
  * the write request format is: Transaction request header + data
  * the read request format is: Transaction request header
  * the write response format is: Transaction response header
  * the read response format is: pure data, no Transaction response header
  */
 #define TRANS_WR_TX_SIZE(n)	(TRANS_REQ_HD_SIZE + SPI_AVMM_VAL_SIZE * (n))
 #define TRANS_RD_TX_SIZE	TRANS_REQ_HD_SIZE
 #define TRANS_TX_MAX		TRANS_WR_TX_SIZE(MAX_WRITE_CNT)

 #define TRANS_RD_RX_SIZE(n)	(SPI_AVMM_VAL_SIZE * (n))
 #define TRANS_WR_RX_SIZE	TRANS_RESP_HD_SIZE
 #define TRANS_RX_MAX		TRANS_RD_RX_SIZE(MAX_READ_CNT)

 /* tx & rx share one transaction layer buffer */
 #define TRANS_BUF_SIZE		((TRANS_TX_MAX > TRANS_RX_MAX) ?	\
 				 TRANS_TX_MAX : TRANS_RX_MAX)

 /*
  * In tx phase, the host prepares all the phy layer bytes of a request in the
  * phy buffer and sends them in a batch.
  *
  * The packet layer and physical layer defines several special chars for
  * various purpose, when a transaction layer byte hits one of these special
  * chars, it should be escaped. The escape rule is, "Escape char first,
  * following the byte XOR'ed with 0x20".
  *
  * This macro defines the max possible length of the phy data. In the worst
  * case, all transaction layer bytes need to be escaped (so the data length
  * doubles), plus 4 special chars (SOP, CHANNEL, CHANNEL_NUM, EOP). Finally
  * we should make sure the length is aligned to SPI BPW.
  */
 #define PHY_TX_MAX		ALIGN(2 * TRANS_TX_MAX + 4, 4)

 /*
  * Unlike tx, phy rx is affected by possible PHY_IDLE bytes from slave, the max
  * length of the rx bit stream is unpredictable. So the driver reads the words
  * one by one, and parses each word immediately into transaction layer buffer.
  * Only one word length of phy buffer is used for rx.
  */
 #define PHY_BUF_SIZE		PHY_TX_MAX

 /**
  * struct spi_avmm_bridge - SPI slave to AVMM bus master bridge
  *
  * @spi: spi slave associated with this bridge.
  * @word_len: bytes of word for spi transfer.
  * @trans_len: length of valid data in trans_buf.
  * @phy_len: length of valid data in phy_buf.
  * @trans_buf: the bridge buffer for transaction layer data.
  * @phy_buf: the bridge buffer for physical layer data.
  * @swap_words: the word swapping cb for phy data. NULL if not needed.
  *
  * As a device's registers are implemented on the AVMM bus address space, it
  * requires the driver to issue formatted requests to spi slave to AVMM bus
  * master bridge to perform register access.
  */
 struct spi_avmm_bridge {
 	struct spi_device *spi;
 	unsigned char word_len;
 	unsigned int trans_len;
 	unsigned int phy_len;
 	/* bridge buffer used in translation between protocol layers */
 	char trans_buf[TRANS_BUF_SIZE];
 	char phy_buf[PHY_BUF_SIZE];
 	void (*swap_words)(char *buf, unsigned int len);
 };

 static void br_swap_words_32(char *buf, unsigned int len)
 {
 	u32 *p = (u32 *)buf;
 	unsigned int count;

 	count = len / 4;
 	while (count--) {
 		*p = swab32p(p);
 		p++;
 	}
 }

 /*
  * Format transaction layer data in br->trans_buf according to the register
  * access request, Store valid transaction layer data length in br->trans_len.
  */
 static int br_trans_tx_prepare(struct spi_avmm_bridge *br, bool is_read, u32 reg,
 			       u32 *wr_val, u32 count)
 {
 	struct trans_req_header *header;
 	unsigned int trans_len;
 	u8 code;
 	__le32 *data;
 	int i;

 	if (is_read) {
 		if (count == 1)
 			code = TRANS_CODE_READ;
 		else
 			code = TRANS_CODE_SEQ_READ;
 	} else {
 		if (count == 1)
 			code = TRANS_CODE_WRITE;
 		else
 			code = TRANS_CODE_SEQ_WRITE;
 	}

 	header = (struct trans_req_header *)br->trans_buf;
 	header->code = code;
 	header->rsvd = 0;
 	header->size = cpu_to_be16((u16)count * SPI_AVMM_VAL_SIZE);
 	header->addr = cpu_to_be32(reg);

 	trans_len = TRANS_REQ_HD_SIZE;

 	if (!is_read) {
 		trans_len += SPI_AVMM_VAL_SIZE * count;
 		if (trans_len > sizeof(br->trans_buf))
 			return -ENOMEM;

 		data = (__le32 *)(br->trans_buf + TRANS_REQ_HD_SIZE);

 		for (i = 0; i < count; i++)
 			*data++ = cpu_to_le32(*wr_val++);
 	}

 	/* Store valid trans data length for next layer */
 	br->trans_len = trans_len;

 	return 0;
 }

 /*
  * Convert transaction layer data (in br->trans_buf) to phy layer data, store
  * them in br->phy_buf. Pad the phy_buf aligned with SPI's BPW. Store valid phy
  * layer data length in br->phy_len.
  *
  * phy_buf len should be aligned with SPI's BPW. Spare bytes should be padded
  * with PHY_IDLE, then the slave will just drop them.
  *
  * The driver will not simply pad 4a at the tail. The concern is that driver
  * will not store MISO data during tx phase, if the driver pads 4a at the tail,
  * it is possible that if the slave is fast enough to response at the padding
  * time. As a result these rx bytes are lost. In the following case, 7a,7c,00
  * will lost.
  * MOSI ...|7a|7c|00|10| |00|00|04|02| |4b|7d|5a|7b| |40|4a|4a|4a| |XX|XX|...
  * MISO ...|4a|4a|4a|4a| |4a|4a|4a|4a| |4a|4a|4a|4a| |4a|7a|7c|00| |78|56|...
  *
  * So the driver moves EOP and bytes after EOP to the end of the aligned size,
  * then fill the hole with PHY_IDLE. As following:
  * before pad ...|7a|7c|00|10| |00|00|04|02| |4b|7d|5a|7b| |40|
  * after pad  ...|7a|7c|00|10| |00|00|04|02| |4b|7d|5a|4a| |4a|4a|7b|40|
  * Then if the slave will not get the entire packet before the tx phase is
  * over, it can't responsed to anything either.
  */
 static int br_pkt_phy_tx_prepare(struct spi_avmm_bridge *br)
 {
 	char *tb, *tb_end, *pb, *pb_limit, *pb_eop = NULL;
 	unsigned int aligned_phy_len, move_size;
 	bool need_esc = false;

 	tb = br->trans_buf;
 	tb_end = tb + br->trans_len;
 	pb = br->phy_buf;
 	pb_limit = pb + ARRAY_SIZE(br->phy_buf);

 	*pb++ = PKT_SOP;

 	/*
 	 * The driver doesn't support multiple channels so the channel number
 	 * is always 0.
 	 */
 	*pb++ = PKT_CHANNEL;
 	*pb++ = 0x0;

 	for (; pb < pb_limit && tb < tb_end; pb++) {
 		if (need_esc) {
 			*pb = *tb++ ^ 0x20;
 			need_esc = false;
 			continue;
 		}

 		/* EOP should be inserted before the last valid char */
 		if (tb == tb_end - 1 && !pb_eop) {
 			*pb = PKT_EOP;
 			pb_eop = pb;
 			continue;
 		}

 		/*
 		 * insert an ESCAPE char if the data value equals any special
 		 * char.
 		 */
 		switch (*tb) {
 		case PKT_SOP:
 		case PKT_EOP:
 		case PKT_CHANNEL:
 		case PKT_ESC:
 			*pb = PKT_ESC;
 			need_esc = true;
 			break;
 		case PHY_IDLE:
 		case PHY_ESC:
 			*pb = PHY_ESC;
 			need_esc = true;
 			break;
 		default:
 			*pb = *tb++;
 			break;
 		}
 	}

 	/* The phy buffer is used out but transaction layer data remains */
 	if (tb < tb_end)
 		return -ENOMEM;

 	/* Store valid phy data length for spi transfer */
 	br->phy_len = pb - br->phy_buf;

 	if (br->word_len == 1)
 		return 0;

 	/* Do phy buf padding if word_len > 1 byte. */
 	aligned_phy_len = ALIGN(br->phy_len, br->word_len);
 	if (aligned_phy_len > sizeof(br->phy_buf))
 		return -ENOMEM;

 	if (aligned_phy_len == br->phy_len)
 		return 0;

 	/* move EOP and bytes after EOP to the end of aligned size */
 	move_size = pb - pb_eop;
 	memmove(&br->phy_buf[aligned_phy_len - move_size], pb_eop, move_size);

 	/* fill the hole with PHY_IDLEs */
 	memset(pb_eop, PHY_IDLE, aligned_phy_len - br->phy_len);

 	/* update the phy data length */
 	br->phy_len = aligned_phy_len;

 	return 0;
 }

 /*
  * In tx phase, the slave only returns PHY_IDLE (0x4a). So the driver will
  * ignore rx in tx phase.
  */
 static int br_do_tx(struct spi_avmm_bridge *br)
 {
 	/* reorder words for spi transfer */
 	if (br->swap_words)
 		br->swap_words(br->phy_buf, br->phy_len);

 	/* send all data in phy_buf  */
 	return spi_write(br->spi, br->phy_buf, br->phy_len);
 }

 /*
  * This function read the rx byte stream from SPI word by word and convert
  * them to transaction layer data in br->trans_buf. It also stores the length
  * of rx transaction layer data in br->trans_len
  *
  * The slave may send an unknown number of PHY_IDLEs in rx phase, so we cannot
  * prepare a fixed length buffer to receive all of the rx data in a batch. We
  * have to read word by word and convert them to transaction layer data at
  * once.
  */
 static int br_do_rx_and_pkt_phy_parse(struct spi_avmm_bridge *br)
 {
 	bool eop_found = false, channel_found = false, esc_found = false;
 	bool valid_word = false, last_try = false;
 	struct device *dev = &br->spi->dev;
 	char *pb, *tb_limit, *tb = NULL;
 	unsigned long poll_timeout;
 	int ret, i;

 	tb_limit = br->trans_buf + ARRAY_SIZE(br->trans_buf);
 	pb = br->phy_buf;
 	poll_timeout = jiffies + SPI_AVMM_XFER_TIMEOUT;
 	while (tb < tb_limit) {
 		ret = spi_read(br->spi, pb, br->word_len);
 		if (ret)
 			return ret;

 		/* reorder the word back */
 		if (br->swap_words)
 			br->swap_words(pb, br->word_len);

 		valid_word = false;
 		for (i = 0; i < br->word_len; i++) {
 			/* drop everything before first SOP */
 			if (!tb && pb[i] != PKT_SOP)
 				continue;

 			/* drop PHY_IDLE */
 			if (pb[i] == PHY_IDLE)
 				continue;

 			valid_word = true;

 			/*
 			 * We don't support multiple channels, so error out if
 			 * a non-zero channel number is found.
 			 */
 			if (channel_found) {
 				if (pb[i] != 0) {
 					dev_err(dev, "%s channel num != 0\n",
 						__func__);
 					return -EFAULT;
 				}

 				channel_found = false;
 				continue;
 			}

 			switch (pb[i]) {
 			case PKT_SOP:
 				/*
 				 * reset the parsing if a second SOP appears.
 				 */
 				tb = br->trans_buf;
 				eop_found = false;
 				channel_found = false;
 				esc_found = false;
 				break;
 			case PKT_EOP:
 				/*
 				 * No special char is expected after ESC char.
 				 * No special char (except ESC & PHY_IDLE) is
 				 * expected after EOP char.
 				 *
 				 * The special chars are all dropped.
 				 */
 				if (esc_found || eop_found)
 					return -EFAULT;

 				eop_found = true;
 				break;
 			case PKT_CHANNEL:
 				if (esc_found || eop_found)
 					return -EFAULT;

 				channel_found = true;
 				break;
 			case PKT_ESC:
 			case PHY_ESC:
 				if (esc_found)
 					return -EFAULT;

 				esc_found = true;
 				break;
 			default:
 				/* Record the normal byte in trans_buf. */
 				if (esc_found) {
 					*tb++ = pb[i] ^ 0x20;
 					esc_found = false;
 				} else {
 					*tb++ = pb[i];
 				}

 				/*
 				 * We get the last normal byte after EOP, it is
 				 * time we finish. Normally the function should
 				 * return here.
 				 */
 				if (eop_found) {
 					br->trans_len = tb - br->trans_buf;
 					return 0;
 				}
 			}
 		}

 		if (valid_word) {
 			/* update poll timeout when we get valid word */
 			poll_timeout = jiffies + SPI_AVMM_XFER_TIMEOUT;
 			last_try = false;
 		} else {
 			/*
 			 * We timeout when rx keeps invalid for some time. But
 			 * it is possible we are scheduled out for long time
 			 * after a spi_read. So when we are scheduled in, a SW
 			 * timeout happens. But actually HW may have worked fine and
 			 * has been ready long time ago. So we need to do an extra
 			 * read, if we get a valid word then we could continue rx,
 			 * otherwise real a HW issue happens.
 			 */
 			if (last_try)
 				return -ETIMEDOUT;

 			if (time_after(jiffies, poll_timeout))
 				last_try = true;
 		}
 	}

 	/*
 	 * We have used out all transfer layer buffer but cannot find the end
 	 * of the byte stream.
 	 */
 	dev_err(dev, "%s transfer buffer is full but rx doesn't end\n",
 		__func__);

 	return -EFAULT;
 }

 /*
  * For read transactions, the avmm bus will directly return register values
  * without transaction response header.
  */
 static int br_rd_trans_rx_parse(struct spi_avmm_bridge *br,
 				u32 *val, unsigned int expected_count)
 {
 	unsigned int i, trans_len = br->trans_len;
 	__le32 *data;

 	if (expected_count * SPI_AVMM_VAL_SIZE != trans_len)
 		return -EFAULT;

 	data = (__le32 *)br->trans_buf;
 	for (i = 0; i < expected_count; i++)
 		*val++ = le32_to_cpu(*data++);

 	return 0;
 }

 /*
  * For write transactions, the slave will return a transaction response
  * header.
  */
 static int br_wr_trans_rx_parse(struct spi_avmm_bridge *br,
 				unsigned int expected_count)
 {
 	unsigned int trans_len = br->trans_len;
 	struct trans_resp_header *resp;
 	u8 code;
 	u16 val_len;

 	if (trans_len != TRANS_RESP_HD_SIZE)
 		return -EFAULT;

 	resp = (struct trans_resp_header *)br->trans_buf;

 	code = resp->r_code ^ 0x80;
 	val_len = be16_to_cpu(resp->size);
 	if (!val_len || val_len != expected_count * SPI_AVMM_VAL_SIZE)
 		return -EFAULT;

 	/* error out if the trans code doesn't align with the val size */
 	if ((val_len == SPI_AVMM_VAL_SIZE && code != TRANS_CODE_WRITE) ||
 	    (val_len > SPI_AVMM_VAL_SIZE && code != TRANS_CODE_SEQ_WRITE))
 		return -EFAULT;

 	return 0;
 }

 static int do_reg_access(void *context, bool is_read, unsigned int reg,
 			 unsigned int *value, unsigned int count)
 {
 	struct spi_avmm_bridge *br = context;
 	int ret;

 	/* invalidate bridge buffers first */
 	br->trans_len = 0;
 	br->phy_len = 0;

 	ret = br_trans_tx_prepare(br, is_read, reg, value, count);
 	if (ret)
 		return ret;

 	ret = br_pkt_phy_tx_prepare(br);
 	if (ret)
 		return ret;

 	ret = br_do_tx(br);
 	if (ret)
 		return ret;

 	ret = br_do_rx_and_pkt_phy_parse(br);
 	if (ret)
 		return ret;

 	if (is_read)
 		return br_rd_trans_rx_parse(br, value, count);
 	else
 		return br_wr_trans_rx_parse(br, count);
 }

 static int regmap_spi_avmm_gather_write(void *context,
 					const void *reg_buf, size_t reg_len,
 					const void *val_buf, size_t val_len)
 {
 	if (reg_len != SPI_AVMM_REG_SIZE)
 		return -EINVAL;

 	if (!IS_ALIGNED(val_len, SPI_AVMM_VAL_SIZE))
 		return -EINVAL;

 	return do_reg_access(context, false, *(u32 *)reg_buf, (u32 *)val_buf,
 			     val_len / SPI_AVMM_VAL_SIZE);
 }

 static int regmap_spi_avmm_write(void *context, const void *data, size_t bytes)
 {
 	if (bytes < SPI_AVMM_REG_SIZE + SPI_AVMM_VAL_SIZE)
 		return -EINVAL;

 	return regmap_spi_avmm_gather_write(context, data, SPI_AVMM_REG_SIZE,
 					    data + SPI_AVMM_REG_SIZE,
 					    bytes - SPI_AVMM_REG_SIZE);
 }

 static int regmap_spi_avmm_read(void *context,
 				const void *reg_buf, size_t reg_len,
 				void *val_buf, size_t val_len)
 {
 	if (reg_len != SPI_AVMM_REG_SIZE)
 		return -EINVAL;

 	if (!IS_ALIGNED(val_len, SPI_AVMM_VAL_SIZE))
 		return -EINVAL;

 	return do_reg_access(context, true, *(u32 *)reg_buf, val_buf,
 			     (val_len / SPI_AVMM_VAL_SIZE));
 }

 static struct spi_avmm_bridge *
 spi_avmm_bridge_ctx_gen(struct spi_device *spi)
 {
 	struct spi_avmm_bridge *br;

 	if (!spi)
 		return ERR_PTR(-ENODEV);

 	/* Only support BPW == 8 or 32 now. Try 32 BPW first. */
 	spi->mode = SPI_MODE_1;
 	spi->bits_per_word = 32;
 	if (spi_setup(spi)) {
 		spi->bits_per_word = 8;
 		if (spi_setup(spi))
 			return ERR_PTR(-EINVAL);
 	}

 	br = kzalloc(sizeof(*br), GFP_KERNEL);
 	if (!br)
 		return ERR_PTR(-ENOMEM);

 	br->spi = spi;
 	br->word_len = spi->bits_per_word / 8;
 	if (br->word_len == 4) {
 		/*
 		 * The protocol requires little endian byte order but MSB
 		 * first. So driver needs to swap the byte order word by word
 		 * if word length > 1.
 		 */
 		br->swap_words = br_swap_words_32;
 	}

 	return br;
 }

 static void spi_avmm_bridge_ctx_free(void *context)
 {
 	kfree(context);
 }

 static const struct regmap_bus regmap_spi_avmm_bus = {
 	.write = regmap_spi_avmm_write,
 	.gather_write = regmap_spi_avmm_gather_write,
 	.read = regmap_spi_avmm_read,
 	.reg_format_endian_default = REGMAP_ENDIAN_NATIVE,
 	.val_format_endian_default = REGMAP_ENDIAN_NATIVE,
 	.max_raw_read = SPI_AVMM_VAL_SIZE * MAX_READ_CNT,
 	.max_raw_write = SPI_AVMM_VAL_SIZE * MAX_WRITE_CNT,
 	.free_context = spi_avmm_bridge_ctx_free,
 };

 struct regmap *__regmap_init_spi_avmm(struct spi_device *spi,
 				      const struct regmap_config *config,
 				      struct lock_class_key *lock_key,
 				      const char *lock_name)
 {
 	struct spi_avmm_bridge *bridge;
 	struct regmap *map;

 	bridge = spi_avmm_bridge_ctx_gen(spi);
 	if (IS_ERR(bridge))
 		return ERR_CAST(bridge);

 	map = __regmap_init(&spi->dev, &regmap_spi_avmm_bus,
 			    bridge, config, lock_key, lock_name);
 	if (IS_ERR(map)) {
 		spi_avmm_bridge_ctx_free(bridge);
 		return ERR_CAST(map);
 	}

 	return map;
 }
 EXPORT_SYMBOL_GPL(__regmap_init_spi_avmm);

 struct regmap *__devm_regmap_init_spi_avmm(struct spi_device *spi,
 					   const struct regmap_config *config,
 					   struct lock_class_key *lock_key,
 					   const char *lock_name)
 {
 	struct spi_avmm_bridge *bridge;
 	struct regmap *map;

 	bridge = spi_avmm_bridge_ctx_gen(spi);
 	if (IS_ERR(bridge))
 		return ERR_CAST(bridge);

 	map = __devm_regmap_init(&spi->dev, &regmap_spi_avmm_bus,
 				 bridge, config, lock_key, lock_name);
 	if (IS_ERR(map)) {
 		spi_avmm_bridge_ctx_free(bridge);
 		return ERR_CAST(map);
 	}

 	return map;
 }
 EXPORT_SYMBOL_GPL(__devm_regmap_init_spi_avmm);

 MODULE_LICENSE("GPL v2");
	// SPDX-License-Identifier: GPL-2.0
	//
	// Register map access API - SPI AVMM support
	//
	// Copyright (C) 2018-2020 Intel Corporation. All rights reserved.

	#include <linux/module.h>
	#include <linux/regmap.h>
	#include <linux/spi/spi.h>

	/*
	* This driver implements the regmap operations for a generic SPI
	* master to access the registers of the spi slave chip which has an
	* Avalone bus in it.
	*
	* The "SPI slave to Avalon Master Bridge" (spi-avmm) IP should be integrated
	* in the spi slave chip. The IP acts as a bridge to convert encoded streams of
	* bytes from the host to the internal register read/write on Avalon bus. In
	* order to issue register access requests to the slave chip, the host should
	* send formatted bytes that conform to the transfer protocol.
	* The transfer protocol contains 3 layers: transaction layer, packet layer
	* and physical layer.
	*
	* Reference Documents could be found at:
	* https://www.intel.com/content/www/us/en/programmable/documentation/sfo1400787952932.html
	*
	* Chapter "SPI Slave/JTAG to Avalon Master Bridge Cores" is a general
	* introduction to the protocol.
	*
	* Chapter "Avalon Packets to Transactions Converter Core" describes
	* the transaction layer.
	*
	* Chapter "Avalon-ST Bytes to Packets and Packets to Bytes Converter Cores"
	* describes the packet layer.
	*
	* Chapter "Avalon-ST Serial Peripheral Interface Core" describes the
	* physical layer.
	*
	*
	* When host issues a regmap read/write, the driver will transform the request
	* to byte stream layer by layer. It formats the register addr, value and
	* length to the transaction layer request, then converts the request to packet
	* layer bytes stream and then to physical layer bytes stream. Finally the
	* driver sends the formatted byte stream over SPI bus to the slave chip.
	*
	* The spi-avmm IP on the slave chip decodes the byte stream and initiates
	* register read/write on its internal Avalon bus, and then encodes the
	* response to byte stream and sends back to host.
	*
	* The driver receives the byte stream, reverses the 3 layers transformation,
	* and finally gets the response value (read out data for register read,
	* successful written size for register write).
	*/

	#define PKT_SOP 0x7a
	#define PKT_EOP 0x7b
	#define PKT_CHANNEL 0x7c
	#define PKT_ESC 0x7d

	#define PHY_IDLE 0x4a
	#define PHY_ESC 0x4d

	#define TRANS_CODE_WRITE 0x0
	#define TRANS_CODE_SEQ_WRITE 0x4
	#define TRANS_CODE_READ 0x10
	#define TRANS_CODE_SEQ_READ 0x14
	#define TRANS_CODE_NO_TRANS 0x7f

	#define SPI_AVMM_XFER_TIMEOUT (msecs_to_jiffies(200))

	/* slave's register addr is 32 bits */
	#define SPI_AVMM_REG_SIZE 4UL
	/* slave's register value is 32 bits */
	#define SPI_AVMM_VAL_SIZE 4UL

	/*
	* max rx size could be larger. But considering the buffer consuming,
	* it is proper that we limit 1KB xfer at max.
	*/
	#define MAX_READ_CNT 256UL
	#define MAX_WRITE_CNT 1UL

	struct trans_req_header {
	u8 code;
	u8 rsvd;
	__be16 size;
	__be32 addr;
	} __packed;

	struct trans_resp_header {
	u8 r_code;
	u8 rsvd;
	__be16 size;
	} __packed;

	#define TRANS_REQ_HD_SIZE (sizeof(struct trans_req_header))
	#define TRANS_RESP_HD_SIZE (sizeof(struct trans_resp_header))

	/*
	* In transaction layer,
	* the write request format is: Transaction request header + data
	* the read request format is: Transaction request header
	* the write response format is: Transaction response header
	* the read response format is: pure data, no Transaction response header
	*/
	#define TRANS_WR_TX_SIZE(n) (TRANS_REQ_HD_SIZE + SPI_AVMM_VAL_SIZE * (n))
	#define TRANS_RD_TX_SIZE TRANS_REQ_HD_SIZE
	#define TRANS_TX_MAX TRANS_WR_TX_SIZE(MAX_WRITE_CNT)

	#define TRANS_RD_RX_SIZE(n) (SPI_AVMM_VAL_SIZE * (n))
	#define TRANS_WR_RX_SIZE TRANS_RESP_HD_SIZE
	#define TRANS_RX_MAX TRANS_RD_RX_SIZE(MAX_READ_CNT)

	/* tx & rx share one transaction layer buffer */
	#define TRANS_BUF_SIZE ((TRANS_TX_MAX > TRANS_RX_MAX) ? \
	TRANS_TX_MAX : TRANS_RX_MAX)

	/*
	* In tx phase, the host prepares all the phy layer bytes of a request in the
	* phy buffer and sends them in a batch.
	*
	* The packet layer and physical layer defines several special chars for
	* various purpose, when a transaction layer byte hits one of these special
	* chars, it should be escaped. The escape rule is, "Escape char first,
	* following the byte XOR'ed with 0x20".
	*
	* This macro defines the max possible length of the phy data. In the worst
	* case, all transaction layer bytes need to be escaped (so the data length
	* doubles), plus 4 special chars (SOP, CHANNEL, CHANNEL_NUM, EOP). Finally
	* we should make sure the length is aligned to SPI BPW.
	*/
	#define PHY_TX_MAX ALIGN(2 * TRANS_TX_MAX + 4, 4)

	/*
	* Unlike tx, phy rx is affected by possible PHY_IDLE bytes from slave, the max
	* length of the rx bit stream is unpredictable. So the driver reads the words
	* one by one, and parses each word immediately into transaction layer buffer.
	* Only one word length of phy buffer is used for rx.
	*/
	#define PHY_BUF_SIZE PHY_TX_MAX

	/**
	* struct spi_avmm_bridge - SPI slave to AVMM bus master bridge
	*
	* @spi: spi slave associated with this bridge.
	* @word_len: bytes of word for spi transfer.
	* @trans_len: length of valid data in trans_buf.
	* @phy_len: length of valid data in phy_buf.
	* @trans_buf: the bridge buffer for transaction layer data.
	* @phy_buf: the bridge buffer for physical layer data.
	* @swap_words: the word swapping cb for phy data. NULL if not needed.
	*
	* As a device's registers are implemented on the AVMM bus address space, it
	* requires the driver to issue formatted requests to spi slave to AVMM bus
	* master bridge to perform register access.
	*/
	struct spi_avmm_bridge {
	struct spi_device *spi;
	unsigned char word_len;
	unsigned int trans_len;
	unsigned int phy_len;
	/* bridge buffer used in translation between protocol layers */
	char trans_buf[TRANS_BUF_SIZE];
	char phy_buf[PHY_BUF_SIZE];
	void (swap_words)(char buf, unsigned int len);
	};

	static void br_swap_words_32(char *buf, unsigned int len)
	{
	u32 p = (u32 )buf;
	unsigned int count;

	count = len / 4;
	while (count--) {
	*p = swab32p(p);
	p++;
	}
	}

	/*
	* Format transaction layer data in br->trans_buf according to the register
	* access request, Store valid transaction layer data length in br->trans_len.
	*/
	static int br_trans_tx_prepare(struct spi_avmm_bridge *br, bool is_read, u32 reg,
	u32 *wr_val, u32 count)
	{
	struct trans_req_header *header;
	unsigned int trans_len;
	u8 code;
	__le32 *data;
	int i;

	if (is_read) {
	if (count == 1)
	code = TRANS_CODE_READ;
	else
	code = TRANS_CODE_SEQ_READ;
	} else {
	if (count == 1)
	code = TRANS_CODE_WRITE;
	else
	code = TRANS_CODE_SEQ_WRITE;
	}

	header = (struct trans_req_header *)br->trans_buf;
	header->code = code;
	header->rsvd = 0;
	header->size = cpu_to_be16((u16)count * SPI_AVMM_VAL_SIZE);
	header->addr = cpu_to_be32(reg);

	trans_len = TRANS_REQ_HD_SIZE;

	if (!is_read) {
	trans_len += SPI_AVMM_VAL_SIZE * count;
	if (trans_len > sizeof(br->trans_buf))
	return -ENOMEM;

	data = (__le32 *)(br->trans_buf + TRANS_REQ_HD_SIZE);

	for (i = 0; i < count; i++)
	data++ = cpu_to_le32(wr_val++);
	}

	/* Store valid trans data length for next layer */
	br->trans_len = trans_len;

	return 0;
	}

	/*
	* Convert transaction layer data (in br->trans_buf) to phy layer data, store
	* them in br->phy_buf. Pad the phy_buf aligned with SPI's BPW. Store valid phy
	* layer data length in br->phy_len.
	*
	* phy_buf len should be aligned with SPI's BPW. Spare bytes should be padded
	* with PHY_IDLE, then the slave will just drop them.
	*
	* The driver will not simply pad 4a at the tail. The concern is that driver
	* will not store MISO data during tx phase, if the driver pads 4a at the tail,
	* it is possible that if the slave is fast enough to response at the padding
	* time. As a result these rx bytes are lost. In the following case, 7a,7c,00
	* will lost.
	* MOSI ...\|7a\|7c\|00\|10\| \|00\|00\|04\|02\| \|4b\|7d\|5a\|7b\| \|40\|4a\|4a\|4a\| \|XX\|XX\|...
	* MISO ...\|4a\|4a\|4a\|4a\| \|4a\|4a\|4a\|4a\| \|4a\|4a\|4a\|4a\| \|4a\|7a\|7c\|00\| \|78\|56\|...
	*
	* So the driver moves EOP and bytes after EOP to the end of the aligned size,
	* then fill the hole with PHY_IDLE. As following:
	* before pad ...\|7a\|7c\|00\|10\| \|00\|00\|04\|02\| \|4b\|7d\|5a\|7b\| \|40\|
	* after pad ...\|7a\|7c\|00\|10\| \|00\|00\|04\|02\| \|4b\|7d\|5a\|4a\| \|4a\|4a\|7b\|40\|
	* Then if the slave will not get the entire packet before the tx phase is
	* over, it can't responsed to anything either.
	*/
	static int br_pkt_phy_tx_prepare(struct spi_avmm_bridge *br)
	{
	char tb, tb_end, pb, pb_limit, *pb_eop = NULL;
	unsigned int aligned_phy_len, move_size;
	bool need_esc = false;

	tb = br->trans_buf;
	tb_end = tb + br->trans_len;
	pb = br->phy_buf;
	pb_limit = pb + ARRAY_SIZE(br->phy_buf);

	*pb++ = PKT_SOP;

	/*
	* The driver doesn't support multiple channels so the channel number
	* is always 0.
	*/
	*pb++ = PKT_CHANNEL;
	*pb++ = 0x0;

	for (; pb < pb_limit && tb < tb_end; pb++) {
	if (need_esc) {
	pb = tb++ ^ 0x20;
	need_esc = false;
	continue;
	}

	/* EOP should be inserted before the last valid char */
	if (tb == tb_end - 1 && !pb_eop) {
	*pb = PKT_EOP;
	pb_eop = pb;
	continue;
	}

	/*
	* insert an ESCAPE char if the data value equals any special
	* char.
	*/
	switch (*tb) {
	case PKT_SOP:
	case PKT_EOP:
	case PKT_CHANNEL:
	case PKT_ESC:
	*pb = PKT_ESC;
	need_esc = true;
	break;
	case PHY_IDLE:
	case PHY_ESC:
	*pb = PHY_ESC;
	need_esc = true;
	break;
	default:
	pb = tb++;
	break;
	}
	}

	/* The phy buffer is used out but transaction layer data remains */
	if (tb < tb_end)
	return -ENOMEM;

	/* Store valid phy data length for spi transfer */
	br->phy_len = pb - br->phy_buf;

	if (br->word_len == 1)
	return 0;

	/* Do phy buf padding if word_len > 1 byte. */
	aligned_phy_len = ALIGN(br->phy_len, br->word_len);
	if (aligned_phy_len > sizeof(br->phy_buf))
	return -ENOMEM;

	if (aligned_phy_len == br->phy_len)
	return 0;

	/* move EOP and bytes after EOP to the end of aligned size */
	move_size = pb - pb_eop;
	memmove(&br->phy_buf[aligned_phy_len - move_size], pb_eop, move_size);

	/* fill the hole with PHY_IDLEs */
	memset(pb_eop, PHY_IDLE, aligned_phy_len - br->phy_len);

	/* update the phy data length */
	br->phy_len = aligned_phy_len;

	return 0;
	}

	/*
	* In tx phase, the slave only returns PHY_IDLE (0x4a). So the driver will
	* ignore rx in tx phase.
	*/
	static int br_do_tx(struct spi_avmm_bridge *br)
	{
	/* reorder words for spi transfer */
	if (br->swap_words)
	br->swap_words(br->phy_buf, br->phy_len);

	/* send all data in phy_buf */
	return spi_write(br->spi, br->phy_buf, br->phy_len);
	}

	/*
	* This function read the rx byte stream from SPI word by word and convert
	* them to transaction layer data in br->trans_buf. It also stores the length
	* of rx transaction layer data in br->trans_len
	*
	* The slave may send an unknown number of PHY_IDLEs in rx phase, so we cannot
	* prepare a fixed length buffer to receive all of the rx data in a batch. We
	* have to read word by word and convert them to transaction layer data at
	* once.
	*/
	static int br_do_rx_and_pkt_phy_parse(struct spi_avmm_bridge *br)
	{
	bool eop_found = false, channel_found = false, esc_found = false;
	bool valid_word = false, last_try = false;
	struct device *dev = &br->spi->dev;
	char pb, tb_limit, *tb = NULL;
	unsigned long poll_timeout;
	int ret, i;

	tb_limit = br->trans_buf + ARRAY_SIZE(br->trans_buf);
	pb = br->phy_buf;
	poll_timeout = jiffies + SPI_AVMM_XFER_TIMEOUT;
	while (tb < tb_limit) {
	ret = spi_read(br->spi, pb, br->word_len);
	if (ret)
	return ret;

	/* reorder the word back */
	if (br->swap_words)
	br->swap_words(pb, br->word_len);

	valid_word = false;
	for (i = 0; i < br->word_len; i++) {
	/* drop everything before first SOP */
	if (!tb && pb[i] != PKT_SOP)
	continue;

	/* drop PHY_IDLE */
	if (pb[i] == PHY_IDLE)
	continue;

	valid_word = true;

	/*
	* We don't support multiple channels, so error out if
	* a non-zero channel number is found.
	*/
	if (channel_found) {
	if (pb[i] != 0) {
	dev_err(dev, "%s channel num != 0\n",
	__func__);
	return -EFAULT;
	}

	channel_found = false;
	continue;
	}

	switch (pb[i]) {
	case PKT_SOP:
	/*
	* reset the parsing if a second SOP appears.
	*/
	tb = br->trans_buf;
	eop_found = false;
	channel_found = false;
	esc_found = false;
	break;
	case PKT_EOP:
	/*
	* No special char is expected after ESC char.
	* No special char (except ESC & PHY_IDLE) is
	* expected after EOP char.
	*
	* The special chars are all dropped.
	*/
	if (esc_found \|\| eop_found)
	return -EFAULT;

	eop_found = true;
	break;
	case PKT_CHANNEL:
	if (esc_found \|\| eop_found)
	return -EFAULT;

	channel_found = true;
	break;
	case PKT_ESC:
	case PHY_ESC:
	if (esc_found)
	return -EFAULT;

	esc_found = true;
	break;
	default:
	/* Record the normal byte in trans_buf. */
	if (esc_found) {
	*tb++ = pb[i] ^ 0x20;
	esc_found = false;
	} else {
	*tb++ = pb[i];
	}

	/*
	* We get the last normal byte after EOP, it is
	* time we finish. Normally the function should
	* return here.
	*/
	if (eop_found) {
	br->trans_len = tb - br->trans_buf;
	return 0;
	}
	}
	}

	if (valid_word) {
	/* update poll timeout when we get valid word */
	poll_timeout = jiffies + SPI_AVMM_XFER_TIMEOUT;
	last_try = false;
	} else {
	/*
	* We timeout when rx keeps invalid for some time. But
	* it is possible we are scheduled out for long time
	* after a spi_read. So when we are scheduled in, a SW
	* timeout happens. But actually HW may have worked fine and
	* has been ready long time ago. So we need to do an extra
	* read, if we get a valid word then we could continue rx,
	* otherwise real a HW issue happens.
	*/
	if (last_try)
	return -ETIMEDOUT;

	if (time_after(jiffies, poll_timeout))
	last_try = true;
	}
	}

	/*
	* We have used out all transfer layer buffer but cannot find the end
	* of the byte stream.
	*/
	dev_err(dev, "%s transfer buffer is full but rx doesn't end\n",
	__func__);

	return -EFAULT;
	}

	/*
	* For read transactions, the avmm bus will directly return register values
	* without transaction response header.
	*/
	static int br_rd_trans_rx_parse(struct spi_avmm_bridge *br,
	u32 *val, unsigned int expected_count)
	{
	unsigned int i, trans_len = br->trans_len;
	__le32 *data;

	if (expected_count * SPI_AVMM_VAL_SIZE != trans_len)
	return -EFAULT;

	data = (__le32 *)br->trans_buf;
	for (i = 0; i < expected_count; i++)
	val++ = le32_to_cpu(data++);

	return 0;
	}

	/*
	* For write transactions, the slave will return a transaction response
	* header.
	*/
	static int br_wr_trans_rx_parse(struct spi_avmm_bridge *br,
	unsigned int expected_count)
	{
	unsigned int trans_len = br->trans_len;
	struct trans_resp_header *resp;
	u8 code;
	u16 val_len;

	if (trans_len != TRANS_RESP_HD_SIZE)
	return -EFAULT;

	resp = (struct trans_resp_header *)br->trans_buf;

	code = resp->r_code ^ 0x80;
	val_len = be16_to_cpu(resp->size);
	if (!val_len \|\| val_len != expected_count * SPI_AVMM_VAL_SIZE)
	return -EFAULT;

	/* error out if the trans code doesn't align with the val size */
	if ((val_len == SPI_AVMM_VAL_SIZE && code != TRANS_CODE_WRITE) \|\|
	(val_len > SPI_AVMM_VAL_SIZE && code != TRANS_CODE_SEQ_WRITE))
	return -EFAULT;

	return 0;
	}

	static int do_reg_access(void *context, bool is_read, unsigned int reg,
	unsigned int *value, unsigned int count)
	{
	struct spi_avmm_bridge *br = context;
	int ret;

	/* invalidate bridge buffers first */
	br->trans_len = 0;
	br->phy_len = 0;

	ret = br_trans_tx_prepare(br, is_read, reg, value, count);
	if (ret)
	return ret;

	ret = br_pkt_phy_tx_prepare(br);
	if (ret)
	return ret;

	ret = br_do_tx(br);
	if (ret)
	return ret;

	ret = br_do_rx_and_pkt_phy_parse(br);
	if (ret)
	return ret;

	if (is_read)
	return br_rd_trans_rx_parse(br, value, count);
	else
	return br_wr_trans_rx_parse(br, count);
	}

	static int regmap_spi_avmm_gather_write(void *context,
	const void *reg_buf, size_t reg_len,
	const void *val_buf, size_t val_len)
	{
	if (reg_len != SPI_AVMM_REG_SIZE)
	return -EINVAL;

	if (!IS_ALIGNED(val_len, SPI_AVMM_VAL_SIZE))
	return -EINVAL;

	return do_reg_access(context, false, (u32 )reg_buf, (u32 *)val_buf,
	val_len / SPI_AVMM_VAL_SIZE);
	}

	static int regmap_spi_avmm_write(void context, const void data, size_t bytes)
	{
	if (bytes < SPI_AVMM_REG_SIZE + SPI_AVMM_VAL_SIZE)
	return -EINVAL;

	return regmap_spi_avmm_gather_write(context, data, SPI_AVMM_REG_SIZE,
	data + SPI_AVMM_REG_SIZE,
	bytes - SPI_AVMM_REG_SIZE);
	}

	static int regmap_spi_avmm_read(void *context,
	const void *reg_buf, size_t reg_len,
	void *val_buf, size_t val_len)
	{
	if (reg_len != SPI_AVMM_REG_SIZE)
	return -EINVAL;

	if (!IS_ALIGNED(val_len, SPI_AVMM_VAL_SIZE))
	return -EINVAL;

	return do_reg_access(context, true, (u32 )reg_buf, val_buf,
	(val_len / SPI_AVMM_VAL_SIZE));
	}

	static struct spi_avmm_bridge *
	spi_avmm_bridge_ctx_gen(struct spi_device *spi)
	{
	struct spi_avmm_bridge *br;

	if (!spi)
	return ERR_PTR(-ENODEV);

	/* Only support BPW == 8 or 32 now. Try 32 BPW first. */
	spi->mode = SPI_MODE_1;
	spi->bits_per_word = 32;
	if (spi_setup(spi)) {
	spi->bits_per_word = 8;
	if (spi_setup(spi))
	return ERR_PTR(-EINVAL);
	}

	br = kzalloc(sizeof(*br), GFP_KERNEL);
	if (!br)
	return ERR_PTR(-ENOMEM);

	br->spi = spi;
	br->word_len = spi->bits_per_word / 8;
	if (br->word_len == 4) {
	/*
	* The protocol requires little endian byte order but MSB
	* first. So driver needs to swap the byte order word by word
	* if word length > 1.
	*/
	br->swap_words = br_swap_words_32;
	}

	return br;
	}

	static void spi_avmm_bridge_ctx_free(void *context)
	{
	kfree(context);
	}

	static const struct regmap_bus regmap_spi_avmm_bus = {
	.write = regmap_spi_avmm_write,
	.gather_write = regmap_spi_avmm_gather_write,
	.read = regmap_spi_avmm_read,
	.reg_format_endian_default = REGMAP_ENDIAN_NATIVE,
	.val_format_endian_default = REGMAP_ENDIAN_NATIVE,
	.max_raw_read = SPI_AVMM_VAL_SIZE * MAX_READ_CNT,
	.max_raw_write = SPI_AVMM_VAL_SIZE * MAX_WRITE_CNT,
	.free_context = spi_avmm_bridge_ctx_free,
	};

	struct regmap __regmap_init_spi_avmm(struct spi_device spi,
	const struct regmap_config *config,
	struct lock_class_key *lock_key,
	const char *lock_name)
	{
	struct spi_avmm_bridge *bridge;
	struct regmap *map;

	bridge = spi_avmm_bridge_ctx_gen(spi);
	if (IS_ERR(bridge))
	return ERR_CAST(bridge);

	map = __regmap_init(&spi->dev, &regmap_spi_avmm_bus,
	bridge, config, lock_key, lock_name);
	if (IS_ERR(map)) {
	spi_avmm_bridge_ctx_free(bridge);
	return ERR_CAST(map);
	}

	return map;
	}
	EXPORT_SYMBOL_GPL(__regmap_init_spi_avmm);

	struct regmap __devm_regmap_init_spi_avmm(struct spi_device spi,
	const struct regmap_config *config,
	struct lock_class_key *lock_key,
	const char *lock_name)
	{
	struct spi_avmm_bridge *bridge;
	struct regmap *map;

	bridge = spi_avmm_bridge_ctx_gen(spi);
	if (IS_ERR(bridge))
	return ERR_CAST(bridge);

	map = __devm_regmap_init(&spi->dev, &regmap_spi_avmm_bus,
	bridge, config, lock_key, lock_name);
	if (IS_ERR(map)) {
	spi_avmm_bridge_ctx_free(bridge);
	return ERR_CAST(map);
	}

	return map;
	}
	EXPORT_SYMBOL_GPL(__devm_regmap_init_spi_avmm);

	MODULE_LICENSE("GPL v2");