[thirdparty/u-boot.git] / tools / kwbimage.h

/* SPDX-License-Identifier: GPL-2.0+ */
/*
 * (C) Copyright 2008
 * Marvell Semiconductor <www.marvell.com>
 * Written-by: Prafulla Wadaskar <prafulla@marvell.com>
 */

#ifndef _KWBIMAGE_H_
#define _KWBIMAGE_H_

#include <compiler.h>
#include <stdint.h>

#ifdef __GNUC__
#define __packed __attribute((packed))
#else
#define __packed
#endif

#define KWBIMAGE_MAX_CONFIG	((0x1dc - 0x20)/sizeof(struct reg_config))
#define MAX_TEMPBUF_LEN		32

/* NAND ECC Mode */
#define IBR_HDR_ECC_DEFAULT		0x00
#define IBR_HDR_ECC_FORCED_HAMMING	0x01
#define IBR_HDR_ECC_FORCED_RS		0x02
#define IBR_HDR_ECC_DISABLED		0x03

/* Boot Type - block ID */
#define IBR_HDR_I2C_ID			0x4D
#define IBR_HDR_SPI_ID			0x5A
#define IBR_HDR_NAND_ID			0x8B
#define IBR_HDR_SATA_ID			0x78
#define IBR_HDR_PEX_ID			0x9C
#define IBR_HDR_UART_ID			0x69
#define IBR_HDR_SDIO_ID			0xAE
#define IBR_DEF_ATTRIB			0x00

/* Structure of the main header, version 0 (Kirkwood, Dove) */
struct main_hdr_v0 {
	uint8_t  blockid;		/* 0x0       */
	uint8_t  nandeccmode;		/* 0x1       */
	uint16_t nandpagesize;		/* 0x2-0x3   */
	uint32_t blocksize;		/* 0x4-0x7   */
	uint8_t  version;		/* 0x8       */
	uint8_t  rsvd1[3];		/* 0x9-0xB   */
	uint32_t srcaddr;		/* 0xC-0xF   */
	uint32_t destaddr;		/* 0x10-0x13 */
	uint32_t execaddr;		/* 0x14-0x17 */
	uint8_t  satapiomode;		/* 0x18      */
	uint8_t  nandblocksize;		/* 0x19      */
	union {
	uint8_t  nandbadblklocation;    /* 0x1A      */
	uint16_t ddrinitdelay;		/* 0x1A-0x1B */
	};
	uint8_t  rsvd2;			/* 0x1C      */
	uint8_t  bin;			/* 0x1D      */
	uint8_t  ext;			/* 0x1E      */
	uint8_t  checksum;		/* 0x1F      */
} __packed;

struct ext_hdr_v0_reg {
	uint32_t raddr;
	uint32_t rdata;
} __packed;

/* Structure of the extension header, version 0 (Kirkwood, Dove) */
struct ext_hdr_v0 {
	/*
	 * Beware that extension header offsets specified in 88AP510 Functional
	 * Specifications are relative to the start of the main header, not to
	 * the start of the extension header itself.
	 */
	uint32_t offset;		/* 0x0-0x3     */
	uint8_t  rsvd1[8];		/* 0x4-0xB     */
	uint32_t enddelay;		/* 0xC-0xF     */
	uint32_t match_addr;		/* 0x10-0x13   */
	uint32_t match_mask;		/* 0x14-0x17   */
	uint32_t match_value;		/* 0x18-0x1B   */
	uint8_t  ddrwritetype;		/* 0x1C        */
	uint8_t  ddrresetmpp;		/* 0x1D        */
	uint8_t  ddrclkenmpp;		/* 0x1E        */
	uint8_t  ddrinitdelay;		/* 0x1F        */
	struct ext_hdr_v0_reg rcfg[55]; /* 0x20-0x1D7  */
	uint8_t  rsvd2[7];		/* 0x1D8-0x1DE */
	uint8_t  checksum;		/* 0x1DF       */
} __packed;

/* Structure of the binary code header, version 0 (Dove) */
struct bin_hdr_v0 {
	uint32_t match_addr;		/* 0x00-0x03  */
	uint32_t match_mask;		/* 0x04-0x07  */
	uint32_t match_value;		/* 0x08-0x0B  */
	uint32_t offset;		/* 0x0C-0x0F  */
	uint32_t destaddr;		/* 0x10-0x13  */
	uint32_t size;			/* 0x14-0x17  */
	uint32_t execaddr;		/* 0x18-0x1B  */
	uint32_t params[4];		/* 0x1C-0x2B  */
	uint8_t  params_flags;		/* 0x2C       */
	uint8_t  rsvd1;			/* 0x2D       */
	uint8_t  rsvd2;			/* 0x2E       */
	uint8_t  checksum;		/* 0x2F       */
	uint8_t  code[2000];		/* 0x30-0x7FF */
} __packed;

/* Structure of the main header, version 1 (Armada 370/XP/375/38x/39x) */
struct main_hdr_v1 {
	uint8_t  blockid;               /* 0x0       */
	uint8_t  flags;                 /* 0x1       */
	uint16_t nandpagesize;          /* 0x2-0x3   */
	uint32_t blocksize;             /* 0x4-0x7   */
	uint8_t  version;               /* 0x8       */
	uint8_t  headersz_msb;          /* 0x9       */
	uint16_t headersz_lsb;          /* 0xA-0xB   */
	uint32_t srcaddr;               /* 0xC-0xF   */
	uint32_t destaddr;              /* 0x10-0x13 */
	uint32_t execaddr;              /* 0x14-0x17 */
	uint8_t  options;               /* 0x18      */
	uint8_t  nandblocksize;         /* 0x19      */
	uint8_t  nandbadblklocation;    /* 0x1A      */
	uint8_t  reserved4;             /* 0x1B      */
	uint16_t reserved5;             /* 0x1C-0x1D */
	uint8_t  ext;                   /* 0x1E      */
	uint8_t  checksum;              /* 0x1F      */
} __packed;

/*
 * Main header options
 */
#define MAIN_HDR_V1_OPT_BAUD_DEFAULT	0
#define MAIN_HDR_V1_OPT_BAUD_2400	0x1
#define MAIN_HDR_V1_OPT_BAUD_4800	0x2
#define MAIN_HDR_V1_OPT_BAUD_9600	0x3
#define MAIN_HDR_V1_OPT_BAUD_19200	0x4
#define MAIN_HDR_V1_OPT_BAUD_38400	0x5
#define MAIN_HDR_V1_OPT_BAUD_57600	0x6
#define MAIN_HDR_V1_OPT_BAUD_115200	0x7

/*
 * Header for the optional headers, version 1 (Armada 370/XP/375/38x/39x)
 */
struct opt_hdr_v1 {
	uint8_t  headertype;
	uint8_t  headersz_msb;
	uint16_t headersz_lsb;
	char     data[0];
} __packed;

/*
 * Public Key data in DER format
 */
struct pubkey_der_v1 {
	uint8_t key[524];
} __packed;

/*
 * Signature (RSA 2048)
 */
struct sig_v1 {
	uint8_t sig[256];
} __packed;

/*
 * Structure of secure header (Armada XP/375/38x/39x)
 */
struct secure_hdr_v1 {
	uint8_t  headertype;		/* 0x0 */
	uint8_t  headersz_msb;		/* 0x1 */
	uint16_t headersz_lsb;		/* 0x2 - 0x3 */
	uint32_t reserved1;		/* 0x4 - 0x7 */
	struct pubkey_der_v1 kak;	/* 0x8 - 0x213 */
	uint8_t  jtag_delay;		/* 0x214 */
	uint8_t  reserved2;		/* 0x215 */
	uint16_t reserved3;		/* 0x216 - 0x217 */
	uint32_t boxid;			/* 0x218 - 0x21B */
	uint32_t flashid;		/* 0x21C - 0x21F */
	struct sig_v1 hdrsig;		/* 0x220 - 0x31F */
	struct sig_v1 imgsig;		/* 0x320 - 0x41F */
	struct pubkey_der_v1 csk[16];	/* 0x420 - 0x24DF */
	struct sig_v1 csksig;		/* 0x24E0 - 0x25DF */
	uint8_t  next;			/* 0x25E0 */
	uint8_t  reserved4;		/* 0x25E1 */
	uint16_t reserved5;		/* 0x25E2 - 0x25E3 */
} __packed;

/*
 * Structure of register set
 */
struct register_set_hdr_v1 {
	uint8_t  headertype;		/* 0x0 */
	uint8_t  headersz_msb;		/* 0x1 */
	uint16_t headersz_lsb;		/* 0x2 - 0x3 */
	union {
		struct {
			uint32_t address;	/* 0x4+8*N - 0x7+8*N */
			uint32_t value;		/* 0x8+8*N - 0xB+8*N */
		} __packed entry;
		struct {
			uint8_t  next;		/* 0xC+8*N */
			uint8_t  delay;		/* 0xD+8*N */
			uint16_t reserved;	/* 0xE+8*N - 0xF+8*N */
		} __packed last_entry;
	} data[];
} __packed;

/*
 * Value 0 in register_set_hdr_v1 delay field is special.
 * Instead of delay it setup SDRAM Controller.
 */
#define REGISTER_SET_HDR_OPT_DELAY_SDRAM_SETUP 0
#define REGISTER_SET_HDR_OPT_DELAY_MS(val) ((val) ?: 1)

/*
 * Various values for the opt_hdr_v1->headertype field, describing the
 * different types of optional headers. The "secure" header contains
 * informations related to secure boot (encryption keys, etc.). The
 * "binary" header contains ARM binary code to be executed prior to
 * executing the main payload (usually the bootloader). This is
 * typically used to execute DDR3 training code. The "register" header
 * allows to describe a set of (address, value) tuples that are
 * generally used to configure the DRAM controller.
 */
#define OPT_HDR_V1_SECURE_TYPE   0x1
#define OPT_HDR_V1_BINARY_TYPE   0x2
#define OPT_HDR_V1_REGISTER_TYPE 0x3

/*
 * Byte 8 of the image header contains the version number. In the v0
 * header, byte 8 was reserved, and always set to 0. In the v1 header,
 * byte 8 has been changed to a proper field, set to 1.
 */
static inline unsigned int kwbimage_version(const void *header)
{
	const unsigned char *ptr = header;
	return ptr[8];
}

static inline size_t kwbheader_size(const void *header)
{
	if (kwbimage_version(header) == 0) {
		const struct main_hdr_v0 *hdr = header;

		/*
		 * First extension header starts immediately after the main
		 * header without any padding. Between extension headers is
		 * 0x20 byte padding. There is no padding after the last
		 * extension header. First binary code header starts immediately
		 * after the last extension header (or immediately after the
		 * main header if there is no extension header) without any
		 * padding. There is no padding between binary code headers and
		 * neither after the last binary code header.
		 */
		return sizeof(*hdr) +
		       hdr->ext * sizeof(struct ext_hdr_v0) +
		       ((hdr->ext > 1) ? ((hdr->ext - 1) * 0x20) : 0) +
		       hdr->bin * sizeof(struct bin_hdr_v0);
	} else {
		const struct main_hdr_v1 *hdr = header;

		return (hdr->headersz_msb << 16) |
		       le16_to_cpu(hdr->headersz_lsb);
	}
}

static inline size_t kwbheader_size_for_csum(const void *header)
{
	if (kwbimage_version(header) == 0)
		return sizeof(struct main_hdr_v0);
	else
		return kwbheader_size(header);
}

static inline struct ext_hdr_v0 *ext_hdr_v0_first(void *img)
{
	struct main_hdr_v0 *mhdr;

	if (kwbimage_version(img) != 0)
		return NULL;

	mhdr = img;
	if (mhdr->ext)
		return (struct ext_hdr_v0 *)(mhdr + 1);
	else
		return NULL;
}

static inline void *_ext_hdr_v0_end(struct main_hdr_v0 *mhdr)
{
	return (uint8_t *)mhdr + kwbheader_size(mhdr) - mhdr->bin * sizeof(struct bin_hdr_v0);
}

static inline struct ext_hdr_v0 *ext_hdr_v0_next(void *img, struct ext_hdr_v0 *cur)
{
	if ((void *)(cur + 1) < _ext_hdr_v0_end(img))
		return (struct ext_hdr_v0 *)((uint8_t *)(cur + 1) + 0x20);
	else
		return NULL;
}

#define for_each_ext_hdr_v0(ehdr, img)			\
	for ((ehdr) = ext_hdr_v0_first((img));		\
	     (ehdr) != NULL;				\
	     (ehdr) = ext_hdr_v0_next((img), (ehdr)))

static inline struct bin_hdr_v0 *bin_hdr_v0_first(void *img)
{
	struct main_hdr_v0 *mhdr;

	if (kwbimage_version(img) != 0)
		return NULL;

	mhdr = img;
	if (mhdr->bin)
		return _ext_hdr_v0_end(mhdr);
	else
		return NULL;
}

#define for_each_bin_hdr_v0(bhdr, img)							\
	for ((bhdr) = bin_hdr_v0_first((img));						\
	     (bhdr) && (void *)(bhdr) < (void *)((uint8_t *)img + kwbheader_size(img));	\
	     (bhdr) = (struct bin_hdr_v0 *)((bhdr))+1)

static inline uint32_t opt_hdr_v1_size(const struct opt_hdr_v1 *ohdr)
{
	return (ohdr->headersz_msb << 16) | le16_to_cpu(ohdr->headersz_lsb);
}

static inline int opt_hdr_v1_valid_size(const struct opt_hdr_v1 *ohdr,
					const void *mhdr_end)
{
	uint32_t ohdr_size;

	if ((const void *)(ohdr + 1) > mhdr_end)
		return 0;

	ohdr_size = opt_hdr_v1_size(ohdr);
	if (ohdr_size < 8 || (const void *)((const uint8_t *)ohdr + ohdr_size) > mhdr_end)
		return 0;

	return 1;
}

static inline struct opt_hdr_v1 *opt_hdr_v1_first(void *img) {
	struct main_hdr_v1 *mhdr;

	if (kwbimage_version(img) != 1)
		return NULL;

	mhdr = img;
	if (mhdr->ext)
		return (struct opt_hdr_v1 *)(mhdr + 1);
	else
		return NULL;
}

static inline uint8_t *opt_hdr_v1_ext(struct opt_hdr_v1 *cur)
{
	uint32_t size = opt_hdr_v1_size(cur);

	return (uint8_t *)cur + size - 4;
}

static inline struct opt_hdr_v1 *_opt_hdr_v1_next(struct opt_hdr_v1 *cur)
{
	return (struct opt_hdr_v1 *)((uint8_t *)cur + opt_hdr_v1_size(cur));
}

static inline struct opt_hdr_v1 *opt_hdr_v1_next(struct opt_hdr_v1 *cur)
{
	if (*opt_hdr_v1_ext(cur))
		return _opt_hdr_v1_next(cur);
	else
		return NULL;
}

#define for_each_opt_hdr_v1(ohdr, img)		\
	for ((ohdr) = opt_hdr_v1_first((img));	\
	     (ohdr) != NULL;			\
	     (ohdr) = opt_hdr_v1_next((ohdr)))

#endif /* _KWBIMAGE_H_ */
Commit	Line	Data
83d290c5	1	/* SPDX-License-Identifier: GPL-2.0+ */
aa0c7a86 PW	2	/*
	3	* (C) Copyright 2008
	4	* Marvell Semiconductor <www.marvell.com>
	5	* Written-by: Prafulla Wadaskar <prafulla@marvell.com>
aa0c7a86 PW	6	*/
	7
	8	#ifndef _KWBIMAGE_H_
	9	#define _KWBIMAGE_H_
	10
a8840dce	11	#include <compiler.h>
aa0c7a86 PW	12	#include <stdint.h>
aa0c7a86 PW	13
a107c61b T	14	#ifdef __GNUC__
	15	#define __packed __attribute((packed))
	16	#else
	17	#define __packed
	18	#endif
	19
aa0c7a86 PW	20	#define KWBIMAGE_MAX_CONFIG ((0x1dc - 0x20)/sizeof(struct reg_config))
	21	#define MAX_TEMPBUF_LEN 32
	22
	23	/* NAND ECC Mode */
	24	#define IBR_HDR_ECC_DEFAULT 0x00
	25	#define IBR_HDR_ECC_FORCED_HAMMING 0x01
0cf207ec WD	26	#define IBR_HDR_ECC_FORCED_RS 0x02
0cf207ec WD	27	#define IBR_HDR_ECC_DISABLED 0x03
aa0c7a86 PW	28
	29	/* Boot Type - block ID */
	30	#define IBR_HDR_I2C_ID 0x4D
	31	#define IBR_HDR_SPI_ID 0x5A
	32	#define IBR_HDR_NAND_ID 0x8B
	33	#define IBR_HDR_SATA_ID 0x78
	34	#define IBR_HDR_PEX_ID 0x9C
	35	#define IBR_HDR_UART_ID 0x69
bd487ce0	36	#define IBR_HDR_SDIO_ID 0xAE
35fd1006	37	#define IBR_DEF_ATTRIB 0x00
aa0c7a86	38
e29f1db3 SR	39	/* Structure of the main header, version 0 (Kirkwood, Dove) */
e29f1db3 SR	40	struct main_hdr_v0 {
37d108b6 BS	41	uint8_t blockid; /* 0x0 */
	42	uint8_t nandeccmode; /* 0x1 */
	43	uint16_t nandpagesize; /* 0x2-0x3 */
	44	uint32_t blocksize; /* 0x4-0x7 */
01bdac6d T	45	uint8_t version; /* 0x8 */
01bdac6d T	46	uint8_t rsvd1[3]; /* 0x9-0xB */
37d108b6 BS	47	uint32_t srcaddr; /* 0xC-0xF */
	48	uint32_t destaddr; /* 0x10-0x13 */
	49	uint32_t execaddr; /* 0x14-0x17 */
	50	uint8_t satapiomode; /* 0x18 */
3917ec57 T	51	uint8_t nandblocksize; /* 0x19 */
	52	union {
	53	uint8_t nandbadblklocation; /* 0x1A */
37d108b6	54	uint16_t ddrinitdelay; /* 0x1A-0x1B */
3917ec57 T	55	};
	56	uint8_t rsvd2; /* 0x1C */
	57	uint8_t bin; /* 0x1D */
37d108b6 BS	58	uint8_t ext; /* 0x1E */
37d108b6 BS	59	uint8_t checksum; /* 0x1F */
a107c61b	60	} __packed;
aa0c7a86	61
e29f1db3	62	struct ext_hdr_v0_reg {
aa0c7a86 PW	63	uint32_t raddr;
aa0c7a86 PW	64	uint32_t rdata;
a107c61b	65	} __packed;
aa0c7a86	66
3917ec57	67	/* Structure of the extension header, version 0 (Kirkwood, Dove) */
e29f1db3	68	struct ext_hdr_v0 {
3917ec57 T	69	/*
	70	* Beware that extension header offsets specified in 88AP510 Functional
	71	* Specifications are relative to the start of the main header, not to
	72	* the start of the extension header itself.
	73	*/
	74	uint32_t offset; /* 0x0-0x3 */
	75	uint8_t rsvd1[8]; /* 0x4-0xB */
	76	uint32_t enddelay; /* 0xC-0xF */
	77	uint32_t match_addr; /* 0x10-0x13 */
	78	uint32_t match_mask; /* 0x14-0x17 */
	79	uint32_t match_value; /* 0x18-0x1B */
	80	uint8_t ddrwritetype; /* 0x1C */
	81	uint8_t ddrresetmpp; /* 0x1D */
	82	uint8_t ddrclkenmpp; /* 0x1E */
	83	uint8_t ddrinitdelay; /* 0x1F */
	84	struct ext_hdr_v0_reg rcfg[55]; /* 0x20-0x1D7 */
	85	uint8_t rsvd2[7]; /* 0x1D8-0x1DE */
	86	uint8_t checksum; /* 0x1DF */
	87	} __packed;
	88
	89	/* Structure of the binary code header, version 0 (Dove) */
	90	struct bin_hdr_v0 {
	91	uint32_t match_addr; /* 0x00-0x03 */
	92	uint32_t match_mask; /* 0x04-0x07 */
	93	uint32_t match_value; /* 0x08-0x0B */
	94	uint32_t offset; /* 0x0C-0x0F */
	95	uint32_t destaddr; /* 0x10-0x13 */
	96	uint32_t size; /* 0x14-0x17 */
	97	uint32_t execaddr; /* 0x18-0x1B */
	98	uint32_t params[4]; /* 0x1C-0x2B */
	99	uint8_t params_flags; /* 0x2C */
	100	uint8_t rsvd1; /* 0x2D */
	101	uint8_t rsvd2; /* 0x2E */
	102	uint8_t checksum; /* 0x2F */
	103	uint8_t code[2000]; /* 0x30-0x7FF */
a107c61b	104	} __packed;
aa0c7a86	105
8010f4ff	106	/* Structure of the main header, version 1 (Armada 370/XP/375/38x/39x) */
e29f1db3	107	struct main_hdr_v1 {
37d108b6 BS	108	uint8_t blockid; /* 0x0 */
37d108b6 BS	109	uint8_t flags; /* 0x1 */
2fdba4f6	110	uint16_t nandpagesize; /* 0x2-0x3 */
37d108b6 BS	111	uint32_t blocksize; /* 0x4-0x7 */
	112	uint8_t version; /* 0x8 */
	113	uint8_t headersz_msb; /* 0x9 */
	114	uint16_t headersz_lsb; /* 0xA-0xB */
	115	uint32_t srcaddr; /* 0xC-0xF */
	116	uint32_t destaddr; /* 0x10-0x13 */
	117	uint32_t execaddr; /* 0x14-0x17 */
	118	uint8_t options; /* 0x18 */
	119	uint8_t nandblocksize; /* 0x19 */
	120	uint8_t nandbadblklocation; /* 0x1A */
	121	uint8_t reserved4; /* 0x1B */
	122	uint16_t reserved5; /* 0x1C-0x1D */
	123	uint8_t ext; /* 0x1E */
	124	uint8_t checksum; /* 0x1F */
a107c61b	125	} __packed;
e29f1db3	126
4bdb5479 CP	127	/*
	128	* Main header options
	129	*/
	130	#define MAIN_HDR_V1_OPT_BAUD_DEFAULT 0
	131	#define MAIN_HDR_V1_OPT_BAUD_2400 0x1
	132	#define MAIN_HDR_V1_OPT_BAUD_4800 0x2
	133	#define MAIN_HDR_V1_OPT_BAUD_9600 0x3
	134	#define MAIN_HDR_V1_OPT_BAUD_19200 0x4
	135	#define MAIN_HDR_V1_OPT_BAUD_38400 0x5
	136	#define MAIN_HDR_V1_OPT_BAUD_57600 0x6
	137	#define MAIN_HDR_V1_OPT_BAUD_115200 0x7
	138
e29f1db3	139	/*
8010f4ff	140	* Header for the optional headers, version 1 (Armada 370/XP/375/38x/39x)
e29f1db3 SR	141	*/
	142	struct opt_hdr_v1 {
	143	uint8_t headertype;
	144	uint8_t headersz_msb;
	145	uint16_t headersz_lsb;
	146	char data[0];
a107c61b	147	} __packed;
e29f1db3	148
a1b6b0a9 MS	149	/*
	150	* Public Key data in DER format
	151	*/
	152	struct pubkey_der_v1 {
	153	uint8_t key[524];
a107c61b	154	} __packed;
a1b6b0a9 MS	155
	156	/*
	157	* Signature (RSA 2048)
	158	*/
	159	struct sig_v1 {
	160	uint8_t sig[256];
a107c61b	161	} __packed;
a1b6b0a9 MS	162
a1b6b0a9 MS	163	/*
8010f4ff	164	* Structure of secure header (Armada XP/375/38x/39x)
a1b6b0a9 MS	165	*/
	166	struct secure_hdr_v1 {
	167	uint8_t headertype; /* 0x0 */
	168	uint8_t headersz_msb; /* 0x1 */
	169	uint16_t headersz_lsb; /* 0x2 - 0x3 */
	170	uint32_t reserved1; /* 0x4 - 0x7 */
	171	struct pubkey_der_v1 kak; /* 0x8 - 0x213 */
	172	uint8_t jtag_delay; /* 0x214 */
	173	uint8_t reserved2; /* 0x215 */
	174	uint16_t reserved3; /* 0x216 - 0x217 */
	175	uint32_t boxid; /* 0x218 - 0x21B */
	176	uint32_t flashid; /* 0x21C - 0x21F */
	177	struct sig_v1 hdrsig; /* 0x220 - 0x31F */
	178	struct sig_v1 imgsig; /* 0x320 - 0x41F */
	179	struct pubkey_der_v1 csk[16]; /* 0x420 - 0x24DF */
	180	struct sig_v1 csksig; /* 0x24E0 - 0x25DF */
	181	uint8_t next; /* 0x25E0 */
	182	uint8_t reserved4; /* 0x25E1 */
	183	uint16_t reserved5; /* 0x25E2 - 0x25E3 */
a107c61b	184	} __packed;
a1b6b0a9	185
02ba70ad T	186	/*
	187	* Structure of register set
	188	*/
	189	struct register_set_hdr_v1 {
	190	uint8_t headertype; /* 0x0 */
	191	uint8_t headersz_msb; /* 0x1 */
	192	uint16_t headersz_lsb; /* 0x2 - 0x3 */
	193	union {
	194	struct {
	195	uint32_t address; /* 0x4+8N - 0x7+8N */
	196	uint32_t value; /* 0x8+8N - 0xB+8N */
a107c61b	197	} __packed entry;
02ba70ad T	198	struct {
	199	uint8_t next; /* 0xC+8N /
	200	uint8_t delay; /* 0xD+8N /
	201	uint16_t reserved; /* 0xE+8N - 0xF+8N */
a107c61b	202	} __packed last_entry;
02ba70ad	203	} data[];
a107c61b	204	} __packed;
02ba70ad T	205
	206	/*
	207	* Value 0 in register_set_hdr_v1 delay field is special.
	208	* Instead of delay it setup SDRAM Controller.
	209	*/
	210	#define REGISTER_SET_HDR_OPT_DELAY_SDRAM_SETUP 0
	211	#define REGISTER_SET_HDR_OPT_DELAY_MS(val) ((val) ?: 1)
	212
e29f1db3 SR	213	/*
	214	* Various values for the opt_hdr_v1->headertype field, describing the
	215	* different types of optional headers. The "secure" header contains
	216	* informations related to secure boot (encryption keys, etc.). The
	217	* "binary" header contains ARM binary code to be executed prior to
	218	* executing the main payload (usually the bootloader). This is
	219	* typically used to execute DDR3 training code. The "register" header
	220	* allows to describe a set of (address, value) tuples that are
	221	* generally used to configure the DRAM controller.
	222	*/
	223	#define OPT_HDR_V1_SECURE_TYPE 0x1
	224	#define OPT_HDR_V1_BINARY_TYPE 0x2
	225	#define OPT_HDR_V1_REGISTER_TYPE 0x3
	226
e29f1db3 SR	227	/*
	228	* Byte 8 of the image header contains the version number. In the v0
	229	* header, byte 8 was reserved, and always set to 0. In the v1 header,
	230	* byte 8 has been changed to a proper field, set to 1.
	231	*/
acb0b38d	232	static inline unsigned int kwbimage_version(const void *header)
e29f1db3	233	{
2ef87f75	234	const unsigned char *ptr = header;
e29f1db3 SR	235	return ptr[8];
	236	}
	237
fe2fd73d MB	238	static inline size_t kwbheader_size(const void *header)
	239	{
	240	if (kwbimage_version(header) == 0) {
	241	const struct main_hdr_v0 *hdr = header;
	242
9a9a2c1a T	243	/*
	244	* First extension header starts immediately after the main
	245	* header without any padding. Between extension headers is
	246	* 0x20 byte padding. There is no padding after the last
	247	* extension header. First binary code header starts immediately
	248	* after the last extension header (or immediately after the
	249	* main header if there is no extension header) without any
	250	* padding. There is no padding between binary code headers and
	251	* neither after the last binary code header.
	252	*/
fe2fd73d	253	return sizeof(*hdr) +
9a9a2c1a T	254	hdr->ext * sizeof(struct ext_hdr_v0) +
	255	((hdr->ext > 1) ? ((hdr->ext - 1) * 0x20) : 0) +
	256	hdr->bin * sizeof(struct bin_hdr_v0);
fe2fd73d MB	257	} else {
	258	const struct main_hdr_v1 *hdr = header;
	259
	260	return (hdr->headersz_msb << 16) \|
	261	le16_to_cpu(hdr->headersz_lsb);
	262	}
	263	}
	264
	265	static inline size_t kwbheader_size_for_csum(const void *header)
	266	{
	267	if (kwbimage_version(header) == 0)
	268	return sizeof(struct main_hdr_v0);
	269	else
	270	return kwbheader_size(header);
	271	}
	272
f76ae257 T	273	static inline struct ext_hdr_v0 ext_hdr_v0_first(void img)
	274	{
	275	struct main_hdr_v0 *mhdr;
	276
	277	if (kwbimage_version(img) != 0)
	278	return NULL;
	279
	280	mhdr = img;
	281	if (mhdr->ext)
	282	return (struct ext_hdr_v0 *)(mhdr + 1);
	283	else
	284	return NULL;
	285	}
	286
	287	static inline void _ext_hdr_v0_end(struct main_hdr_v0 mhdr)
	288	{
	289	return (uint8_t )mhdr + kwbheader_size(mhdr) - mhdr->bin sizeof(struct bin_hdr_v0);
	290	}
	291
	292	static inline struct ext_hdr_v0 ext_hdr_v0_next(void img, struct ext_hdr_v0 *cur)
	293	{
	294	if ((void *)(cur + 1) < _ext_hdr_v0_end(img))
	295	return (struct ext_hdr_v0 )((uint8_t )(cur + 1) + 0x20);
	296	else
	297	return NULL;
	298	}
	299
	300	#define for_each_ext_hdr_v0(ehdr, img) \
	301	for ((ehdr) = ext_hdr_v0_first((img)); \
	302	(ehdr) != NULL; \
	303	(ehdr) = ext_hdr_v0_next((img), (ehdr)))
	304
	305	static inline struct bin_hdr_v0 bin_hdr_v0_first(void img)
	306	{
	307	struct main_hdr_v0 *mhdr;
	308
	309	if (kwbimage_version(img) != 0)
	310	return NULL;
	311
	312	mhdr = img;
	313	if (mhdr->bin)
	314	return _ext_hdr_v0_end(mhdr);
	315	else
	316	return NULL;
	317	}
	318
	319	#define for_each_bin_hdr_v0(bhdr, img) \
	320	for ((bhdr) = bin_hdr_v0_first((img)); \
	321	(bhdr) && (void )(bhdr) < (void )((uint8_t *)img + kwbheader_size(img)); \
	322	(bhdr) = (struct bin_hdr_v0 *)((bhdr))+1)
	323
732c930b MB	324	static inline uint32_t opt_hdr_v1_size(const struct opt_hdr_v1 *ohdr)
	325	{
	326	return (ohdr->headersz_msb << 16) \| le16_to_cpu(ohdr->headersz_lsb);
	327	}
	328
	329	static inline int opt_hdr_v1_valid_size(const struct opt_hdr_v1 *ohdr,
	330	const void *mhdr_end)
	331	{
	332	uint32_t ohdr_size;
	333
1a0e52f5	334	if ((const void *)(ohdr + 1) > mhdr_end)
732c930b MB	335	return 0;
	336
	337	ohdr_size = opt_hdr_v1_size(ohdr);
1a0e52f5	338	if (ohdr_size < 8 \|\| (const void )((const uint8_t )ohdr + ohdr_size) > mhdr_end)
732c930b MB	339	return 0;
	340
	341	return 1;
	342	}
	343
	344	static inline struct opt_hdr_v1 opt_hdr_v1_first(void img) {
	345	struct main_hdr_v1 *mhdr;
	346
acb0b38d	347	if (kwbimage_version(img) != 1)
732c930b MB	348	return NULL;
	349
	350	mhdr = img;
44691034	351	if (mhdr->ext)
732c930b MB	352	return (struct opt_hdr_v1 *)(mhdr + 1);
	353	else
	354	return NULL;
	355	}
	356
	357	static inline uint8_t opt_hdr_v1_ext(struct opt_hdr_v1 cur)
	358	{
	359	uint32_t size = opt_hdr_v1_size(cur);
	360
	361	return (uint8_t *)cur + size - 4;
	362	}
	363
	364	static inline struct opt_hdr_v1 _opt_hdr_v1_next(struct opt_hdr_v1 cur)
	365	{
	366	return (struct opt_hdr_v1 )((uint8_t )cur + opt_hdr_v1_size(cur));
	367	}
	368
	369	static inline struct opt_hdr_v1 opt_hdr_v1_next(struct opt_hdr_v1 cur)
	370	{
44691034	371	if (*opt_hdr_v1_ext(cur))
732c930b MB	372	return _opt_hdr_v1_next(cur);
	373	else
	374	return NULL;
	375	}
	376
	377	#define for_each_opt_hdr_v1(ohdr, img) \
	378	for ((ohdr) = opt_hdr_v1_first((img)); \
	379	(ohdr) != NULL; \
	380	(ohdr) = opt_hdr_v1_next((ohdr)))
	381
aa0c7a86	382	#endif /* _KWBIMAGE_H_ */