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* This is a modified version 1.0 of sdb.h, not the official spec version
*/
#ifndef __SDB_H__
#define __SDB_H__
#ifdef __KERNEL__
#include <linux/types.h>
#else
/*
* All structures are 64 bytes long and are expected
* to live in an array, one for each interconnect.
* Most fields of the structures are shared among the
* various types, and most-specific fields are at the
* beginning (for alignment reasons, and to keep the
* magic number at the head of the interconnect record
*/
/* Product, 40 bytes at offset 24, 8-byte aligned
*
* device_id is vendor-assigned; version is device-specific,
* date is hex (e.g 0x20120501), name is UTF-8, blank-filled
* and not terminated with a 0 byte.
*/
struct sdb_product {
uint64_t vendor_id; /* 0x18..0x1f */
uint32_t device_id; /* 0x20..0x23 */
uint32_t version; /* 0x24..0x27 */
uint32_t date; /* 0x28..0x2b */
uint8_t name[19]; /* 0x2c..0x3e */
uint8_t record_type; /* 0x3f */
};
/*
* Component, 56 bytes at offset 8, 8-byte aligned
*
* The address range is first to last, inclusive
* (for example 0x100000 - 0x10ffff)
*/
struct sdb_component {
uint64_t addr_first; /* 0x08..0x0f */
uint64_t addr_last; /* 0x10..0x17 */
struct sdb_product product; /* 0x18..0x3f */
};
/* Type of the SDB record */
enum sdb_record_type {
sdb_type_interconnect = 0x00,
sdb_type_device = 0x01,
sdb_type_bridge = 0x02,
sdb_type_integration = 0x80,
sdb_type_empty = 0xFF,
};
/* Type 0: interconnect (first of the array)
*
* sdb_records is the length of the table including this first
* record, version is 1. The bus type is enumerated later.
#define SDB_MAGIC 0x5344422d /* "SDB-" */
struct sdb_interconnect {
uint32_t sdb_magic; /* 0x00-0x03 */
uint16_t sdb_records; /* 0x04-0x05 */
uint8_t sdb_version; /* 0x06 */
uint8_t sdb_bus_type; /* 0x07 */
struct sdb_component sdb_component; /* 0x08-0x3f */
};
/* Type 1: device
*
* class is 0 for "custom device", other values are
* to be standardized; ABI version is for the driver,
* bus-specific bits are defined by each bus (see below)
*/
struct sdb_device {
uint16_t abi_class; /* 0x00-0x01 */
uint8_t abi_ver_major; /* 0x02 */
uint8_t abi_ver_minor; /* 0x03 */
uint32_t bus_specific; /* 0x04-0x07 */
struct sdb_component sdb_component; /* 0x08-0x3f */
};
/* Type 2: bridge
*
* child is the address of the nested SDB table
*/
struct sdb_bridge {
uint64_t sdb_child; /* 0x00-0x07 */
struct sdb_component sdb_component; /* 0x08-0x3f */
};
/* Type 0x80: integration
*
* all types with bit 7 set are meta-information, so
* software can ignore the types it doesn't know. Here we
* just provide product information for an aggregate device
*/
struct sdb_integration {
uint8_t reserved[24]; /* 0x00-0x17 */
struct sdb_product product; /* 0x08-0x3f */
};
/* Type 0xff: empty
*
* this allows keeping empty slots during development,
* so they can be filled later with minimal efforts and
* no misleading description is ever shipped -- hopefully.
* It can also be used to pad a table to a desired length.
uint8_t reserved[63]; /* 0x00-0x3e */
uint8_t record_type; /* 0x3f */
};
/* The type of bus, for bus-specific flags */
sdb_wishbone = 0x00,
sdb_data = 0x01,
#define SDB_WB_WIDTH_MASK 0x0f
#define SDB_WB_ACCESS8 0x01
#define SDB_WB_ACCESS16 0x02
#define SDB_WB_ACCESS32 0x04
#define SDB_WB_ACCESS64 0x08
#define SDB_WB_LITTLE_ENDIAN 0x80
#define SDB_DATA_READ 0x04
#define SDB_DATA_WRITE 0x02
#define SDB_DATA_EXEC 0x01