doc/imx/common/imx6.txt - u-boot-mtk - Git at Google

 U-Boot for Freescale i.MX6

 This file contains information for the port of U-Boot to the Freescale i.MX6
 SoC.

 1. CONVENTIONS FOR FUSE ASSIGNMENTS
 -----------------------------------

 1.1 MAC Address: It is stored in fuse bank 4, with the 32 lsbs in word 2 and the
     16 msbs in word 3[15:0].
     For i.MX6SX and i.MX6UL, they have two MAC addresses. The second MAC address
     is stored in fuse bank 4, with the 16 lsb in word 3[31:16] and the 32 msbs in
     word 4.

 Example:

 For reading the MAC address fuses on a MX6Q:

 - The MAC address is stored in two fuse addresses (the fuse addresses are
 described in the Fusemap Descriptions table from the mx6q Reference Manual):

 0x620[31:0] - MAC_ADDR[31:0]
 0x630[15:0] - MAC_ADDR[47:32]

 In order to use the fuse API, we need to pass the bank and word values, which
 are calculated as below:

 Fuse address for the lower MAC address: 0x620
 Base address for the fuses: 0x400

 (0x620 - 0x400)/0x10 = 0x22 = 34 decimal

 As the fuses are arranged in banks of 8 words:

 34 / 8 = 4 and the remainder is 2, so in this case:

 bank = 4
 word = 2

 And the U-Boot command would be:

 => fuse read 4 2
 Reading bank 4:

 Word 0x00000002: 9f027772

 Doing the same for the upper MAC address:

 Fuse address for the upper MAC address: 0x630
 Base address for the fuses: 0x400

 (0x630 - 0x400)/0x10 = 0x23 = 35 decimal

 As the fuses are arranged in banks of 8 words:

 35 / 8 = 4 and the remainder is 3, so in this case:

 bank = 4
 word = 3

 And the U-Boot command would be:

 => fuse read 4 3
 Reading bank 4:

 Word 0x00000003: 00000004

 ,which matches the ethaddr value:
 => echo ${ethaddr}
 00:04:9f:02:77:72

 Some other useful hints:

 - The 'bank' and 'word' numbers can be easily obtained from the mx6 Reference
 Manual. For the mx6quad case, please check the "46.5 OCOTP Memory Map/Register
 Definition" from the "i.MX 6Dual/6Quad Applications Processor Reference Manual,
 Rev. 1, 04/2013" document. For example, for the MAC fuses we have:

 Address:
 21B_C620	Value of OTP Bank4 Word2 (MAC Address)(OCOTP_MAC0)

 21B_C630	Value of OTP Bank4 Word3 (MAC Address)(OCOTP_MAC1)

 - The command '=> fuse read 4 2 2' reads the whole MAC addresses at once:

 => fuse read 4 2 2
 Reading bank 4:

 Word 0x00000002: 9f027772 00000004

 NAND Boot on i.MX6 with SPL support
 --------------------------------------

 Writing/updating boot image in nand device is not straight forward in
 i.MX6 platform and it requires boot control block(BCB) to be configured.

 BCB contains two data structures, Firmware Configuration Block(FCB) and
 Discovered Bad Block Table(DBBT). FCB has nand timings, DBBT search area,
 and firmware. See IMX6DQRM Section 8.5.2.2
 for more information.

 We can't use 'nand write' command to write SPL/firmware image directly
 like other platforms does. So we need special setup to write BCB block
 as per IMX6QDL reference manual 'nandbcb update' command do that job.

 for nand boot, up on reset bootrom look for FCB structure in
 first block's if FCB found the nand timings are loaded for
 further reads. once FCB read done, DTTB will be loaded and
 finally firmware will be loaded which is boot image.

 cmd_nandbcb will create FCB these structures
 by taking mtd partition as an example.
 - initial code will erase entire partition
 - followed by FCB setup, like first 2 blocks for FCB/DBBT write,
   and next block for FW1/SPL
 - write firmware at FW1 block and
 - finally write fcb/dttb in first 2 block.

 Typical NAND BCB layout:
 =======================

    no.of blocks = partition size / erasesize
    no.of fcb/dbbt blocks = 2
    FW1 offset = no.of fcb/dbbt

 block  0          1          2
         -------------------------------
        |FCB/DBBT 0|FCB/DBBT 1|  FW 1  |
        --------------------------------

 On summary, nandbcb update will
 - erase the entire partition
 - create BCB by creating 2 FCB/BDDT block followed by
   1 FW blocks based on partition size and erasesize.
 - fill FCB/DBBT structures
 - write FW/SPL in FW1
 - write FCB/DBBT in first 2 blocks

 step-1: write SPL

 icorem6qdl> ext4load mmc 0:1 $loadaddr SPL
 39936 bytes read in 10 ms (3.8 MiB/s)

 icorem6qdl> nandbcb update $loadaddr spl $filesize
 device 0 offset 0x0, size 0x9c00
 Erasing at 0x1c0000 -- 100% complete.
 NAND fw write: 0x80000 offset, 0xb000 bytes written: OK

 step-2: write u-boot-dtb.img

 icorem6qdl> nand erase.part uboot

 NAND erase.part: device 0 offset 0x200000, size 0x200000
 Erasing at 0x3c0000 -- 100% complete.
 OK

 icorem6qdl> ext4load mmc 0:1 $loadaddr u-boot-dtb.img
 589094 bytes read in 37 ms (15.2 MiB/s)

 icorem6qdl> nand write ${loadaddr} uboot ${filesize}

 NAND write: device 0 offset 0x200000, size 0x8fd26
  589094 bytes written: OK
 icorem6qdl>
	U-Boot for Freescale i.MX6

	This file contains information for the port of U-Boot to the Freescale i.MX6
	SoC.

	1. CONVENTIONS FOR FUSE ASSIGNMENTS
	-----------------------------------

	1.1 MAC Address: It is stored in fuse bank 4, with the 32 lsbs in word 2 and the
	16 msbs in word 3[15:0].
	For i.MX6SX and i.MX6UL, they have two MAC addresses. The second MAC address
	is stored in fuse bank 4, with the 16 lsb in word 3[31:16] and the 32 msbs in
	word 4.

	Example:

	For reading the MAC address fuses on a MX6Q:

	- The MAC address is stored in two fuse addresses (the fuse addresses are
	described in the Fusemap Descriptions table from the mx6q Reference Manual):

	0x620[31:0] - MAC_ADDR[31:0]
	0x630[15:0] - MAC_ADDR[47:32]

	In order to use the fuse API, we need to pass the bank and word values, which
	are calculated as below:

	Fuse address for the lower MAC address: 0x620
	Base address for the fuses: 0x400

	(0x620 - 0x400)/0x10 = 0x22 = 34 decimal

	As the fuses are arranged in banks of 8 words:

	34 / 8 = 4 and the remainder is 2, so in this case:

	bank = 4
	word = 2

	And the U-Boot command would be:

	=> fuse read 4 2
	Reading bank 4:

	Word 0x00000002: 9f027772

	Doing the same for the upper MAC address:

	Fuse address for the upper MAC address: 0x630
	Base address for the fuses: 0x400

	(0x630 - 0x400)/0x10 = 0x23 = 35 decimal

	As the fuses are arranged in banks of 8 words:

	35 / 8 = 4 and the remainder is 3, so in this case:

	bank = 4
	word = 3

	And the U-Boot command would be:

	=> fuse read 4 3
	Reading bank 4:

	Word 0x00000003: 00000004

	,which matches the ethaddr value:
	=> echo ${ethaddr}
	00:04:9f:02:77:72

	Some other useful hints:

	- The 'bank' and 'word' numbers can be easily obtained from the mx6 Reference
	Manual. For the mx6quad case, please check the "46.5 OCOTP Memory Map/Register
	Definition" from the "i.MX 6Dual/6Quad Applications Processor Reference Manual,
	Rev. 1, 04/2013" document. For example, for the MAC fuses we have:

	Address:
	21B_C620 Value of OTP Bank4 Word2 (MAC Address)(OCOTP_MAC0)

	21B_C630 Value of OTP Bank4 Word3 (MAC Address)(OCOTP_MAC1)

	- The command '=> fuse read 4 2 2' reads the whole MAC addresses at once:

	=> fuse read 4 2 2
	Reading bank 4:

	Word 0x00000002: 9f027772 00000004

	NAND Boot on i.MX6 with SPL support
	--------------------------------------

	Writing/updating boot image in nand device is not straight forward in
	i.MX6 platform and it requires boot control block(BCB) to be configured.

	BCB contains two data structures, Firmware Configuration Block(FCB) and
	Discovered Bad Block Table(DBBT). FCB has nand timings, DBBT search area,
	and firmware. See IMX6DQRM Section 8.5.2.2
	for more information.

	We can't use 'nand write' command to write SPL/firmware image directly
	like other platforms does. So we need special setup to write BCB block
	as per IMX6QDL reference manual 'nandbcb update' command do that job.

	for nand boot, up on reset bootrom look for FCB structure in
	first block's if FCB found the nand timings are loaded for
	further reads. once FCB read done, DTTB will be loaded and
	finally firmware will be loaded which is boot image.

	cmd_nandbcb will create FCB these structures
	by taking mtd partition as an example.
	- initial code will erase entire partition
	- followed by FCB setup, like first 2 blocks for FCB/DBBT write,
	and next block for FW1/SPL
	- write firmware at FW1 block and
	- finally write fcb/dttb in first 2 block.

	Typical NAND BCB layout:
	=======================

	no.of blocks = partition size / erasesize
	no.of fcb/dbbt blocks = 2
	FW1 offset = no.of fcb/dbbt

	block 0 1 2
	-------------------------------
	\|FCB/DBBT 0\|FCB/DBBT 1\| FW 1 \|
	--------------------------------

	On summary, nandbcb update will
	- erase the entire partition
	- create BCB by creating 2 FCB/BDDT block followed by
	1 FW blocks based on partition size and erasesize.
	- fill FCB/DBBT structures
	- write FW/SPL in FW1
	- write FCB/DBBT in first 2 blocks

	step-1: write SPL

	icorem6qdl> ext4load mmc 0:1 $loadaddr SPL
	39936 bytes read in 10 ms (3.8 MiB/s)

	icorem6qdl> nandbcb update $loadaddr spl $filesize
	device 0 offset 0x0, size 0x9c00
	Erasing at 0x1c0000 -- 100% complete.
	NAND fw write: 0x80000 offset, 0xb000 bytes written: OK

	step-2: write u-boot-dtb.img

	icorem6qdl> nand erase.part uboot

	NAND erase.part: device 0 offset 0x200000, size 0x200000
	Erasing at 0x3c0000 -- 100% complete.
	OK

	icorem6qdl> ext4load mmc 0:1 $loadaddr u-boot-dtb.img
	589094 bytes read in 37 ms (15.2 MiB/s)

	icorem6qdl> nand write ${loadaddr} uboot ${filesize}

	NAND write: device 0 offset 0x200000, size 0x8fd26
	589094 bytes written: OK
	icorem6qdl>