From c8fff5d2b50f9dee96c84c1c71de7b1c2621b702 Mon Sep 17 00:00:00 2001
From: Tom Rini <trini@konsulko.com>
Date: Sat, 11 Sep 2021 08:57:31 -0400
Subject: doc: ti: Convert am335x_evm README to rST

Convert the existing documentation to rST, keeping to just making
formatting changes to start with.

Signed-off-by: Tom Rini <trini@konsulko.com>
---
 doc/board/ti/am335x_evm.rst | 227 ++++++++++++++++++++++++++++++++++++++++++++
 doc/board/ti/index.rst      |   1 +
 2 files changed, 228 insertions(+)
 create mode 100644 doc/board/ti/am335x_evm.rst

(limited to 'doc')

diff --git a/doc/board/ti/am335x_evm.rst b/doc/board/ti/am335x_evm.rst
new file mode 100644
index 0000000..51c11a3
--- /dev/null
+++ b/doc/board/ti/am335x_evm.rst
@@ -0,0 +1,227 @@
+.. SPDX-License-Identifier: GPL-2.0+ OR BSD-3-Clause
+.. sectionauthor:: Tom Rini <trini@konsulko.com>
+
+Summary
+=======
+
+This document covers various features of the 'am335x_evm' build, and some of
+the related build targets (am335x_evm_uartN, etc).
+
+Hardware
+--------
+
+The binary produced by this board supports, based on parsing of the EEPROM
+documented in TI's reference designs:
+* AM335x GP EVM
+* AM335x EVM SK
+* Beaglebone White
+* Beaglebone Black
+
+Customization
+-------------
+
+Given that all of the above boards are reference platforms (and the
+Beaglebone platforms are OSHA), it is likely that this platform code and
+configuration will be used as the basis of a custom platform.  It is
+worth noting that aside from things such as NAND or MMC only being
+required if a custom platform makes use of these blocks, the following
+are required, depending on design:
+
+* GPIO is only required if DDR3 power is controlled in a way similar to EVM SK
+* SPI is only required for SPI flash, or exposing the SPI bus.
+
+The following blocks are required:
+
+* I2C, to talk with the PMIC and ensure that we do not run afoul of
+  errata 1.0.24.
+
+When removing options as part of customization,
+CONFIG_EXTRA_ENV_SETTINGS will need additional care to update for your
+needs and to remove no longer relevant options as in some cases we
+define additional text blocks (such as for NAND or DFU strings).  Also
+note that all of the SPL options are grouped together, rather than with
+the IP blocks, so both areas will need their choices updated to reflect
+the custom design.
+
+NAND
+----
+
+The AM335x GP EVM ships with a 256MiB NAND available in most profiles.  In
+this example to program the NAND we assume that an SD card has been
+inserted with the files to write in the first SD slot and that mtdparts
+have been configured correctly for the board. All images are first loaded
+into memory, then written to NAND.
+
+Step-1: Building u-boot for NAND boot
+	Set following CONFIGxx options for NAND device.
+	CONFIG_SYS_NAND_PAGE_SIZE	number of main bytes in NAND page
+	CONFIG_SYS_NAND_OOBSIZE		number of OOB bytes in NAND page
+	CONFIG_SYS_NAND_BLOCK_SIZE	number of bytes in NAND erase-block
+	CONFIG_SYS_NAND_ECCPOS		ECC map for NAND page
+	CONFIG_NAND_OMAP_ECCSCHEME	(refer doc/README.nand)
+
+Step-2: Flashing NAND via MMC/SD
+
+.. code-block:: text
+
+	# select BOOTSEL to MMC/SD boot and boot from MMC/SD card
+	U-Boot # mmc rescan
+	# erase flash
+	U-Boot # nand erase.chip
+	U-Boot # env default -f -a
+	U-Boot # saveenv
+	# flash MLO. Redundant copies of MLO are kept for failsafe
+	U-Boot # load mmc 0 0x82000000 MLO
+	U-Boot # nand write 0x82000000 0x00000 0x20000
+	U-Boot # nand write 0x82000000 0x20000 0x20000
+	U-Boot # nand write 0x82000000 0x40000 0x20000
+	U-Boot # nand write 0x82000000 0x60000 0x20000
+	# flash u-boot.img
+	U-Boot # load mmc 0 0x82000000 u-boot.img
+	U-Boot # nand write 0x82000000 0x80000 0x60000
+	# flash kernel image
+	U-Boot # load mmc 0 0x82000000 uImage
+	U-Boot # nand write 0x82000000 ${nandsrcaddr} ${nandimgsize}
+	# flash filesystem image
+	U-Boot # load mmc 0 0x82000000 filesystem.img
+	U-Boot # nand write 0x82000000 ${loadaddress} 0x300000
+
+Step-3: Set BOOTSEL pin to select NAND boot, and POR the device.
+	The device should boot from images flashed on NAND device.
+
+NOR
+---
+
+The Beaglebone White can be equipped with a "memory cape" that in turn can
+have a NOR module plugged into it.  In this case it is then possible to
+program and boot from NOR.  Note that due to how U-Boot is designed we
+must build a specific version of U-Boot that knows we have NOR flash.  This
+build is named 'am335x_evm_nor'.  Further, we have a 'am335x_evm_norboot'
+build that will assume that the environment is on NOR rather than NAND.  In
+the following example we assume that and SD card has been populated with
+MLO and u-boot.img from a 'am335x_evm_nor' build and also contains the
+'u-boot.bin' from a 'am335x_evm_norboot' build.  When booting from NOR, a
+binary must be written to the start of NOR, with no header or similar
+prepended.  In the following example we use a size of 512KiB (0x80000)
+as that is how much space we set aside before the environment, as per
+the config file.
+
+.. code-block:: text
+
+	U-Boot # mmc rescan
+	U-Boot # load mmc 0 ${loadaddr} u-boot.bin
+	U-Boot # protect off 08000000 +80000
+	U-Boot # erase 08000000 +80000
+	U-Boot # cp.b ${loadaddr} 08000000 ${filesize}
+
+Falcon Mode
+-----------
+
+The default build includes "Falcon Mode" (see doc/README.falcon) via NAND,
+eMMC (or raw SD cards) and FAT SD cards.  Our default behavior currently is
+to read a 'c' on the console while in SPL at any point prior to loading the
+OS payload (so as soon as possible) to opt to booting full U-Boot.  Also
+note that while one can program Falcon Mode "in place" great care needs to
+be taken by the user to not 'brick' their setup.  As these are all eval
+boards with multiple boot methods, recovery should not be an issue in this
+worst-case however.
+
+Falcon Mode: eMMC
+-----------------
+
+The recommended layout in this case is:
+
+.. code-block:: text
+
+	MMC BLOCKS      |--------------------------------| LOCATION IN BYTES
+	0x0000 - 0x007F : MBR or GPT table               : 0x000000 - 0x020000
+	0x0080 - 0x00FF : ARGS or FDT file               : 0x010000 - 0x020000
+	0x0100 - 0x01FF : SPL.backup1 (first copy used)  : 0x020000 - 0x040000
+	0x0200 - 0x02FF : SPL.backup2 (second copy used) : 0x040000 - 0x060000
+	0x0300 - 0x06FF : U-Boot                         : 0x060000 - 0x0e0000
+	0x0700 - 0x08FF : U-Boot Env + Redundant         : 0x0e0000 - 0x120000
+	0x0900 - 0x28FF : Kernel                         : 0x120000 - 0x520000
+
+Note that when we run 'spl export' it will prepare to boot the kernel.
+This includes relocation of the uImage from where we loaded it to the entry
+point defined in the header.  As these locations overlap by default, it
+would leave us with an image that if written to MMC will not boot, so
+instead of using the loadaddr variable we use 0x81000000 in the following
+example.  In this example we are loading from the network, for simplicity,
+and assume a valid partition table already exists and 'mmc dev' has already
+been run to select the correct device.  Also note that if you previously
+had a FAT partition (such as on a Beaglebone Black) it is not enough to
+write garbage into the area, you must delete it from the partition table
+first.
+
+.. code-block:: text
+
+	# Ensure we are able to talk with this mmc device
+	U-Boot # mmc rescan
+	U-Boot # tftp 81000000 am335x/MLO
+	# Write to two of the backup locations ROM uses
+	U-Boot # mmc write 81000000 100 100
+	U-Boot # mmc write 81000000 200 100
+	# Write U-Boot to the location set in the config
+	U-Boot # tftp 81000000 am335x/u-boot.img
+	U-Boot # mmc write 81000000 300 400
+	# Load kernel and device tree into memory, perform export
+	U-Boot # tftp 81000000 am335x/uImage
+	U-Boot # run findfdt
+	U-Boot # tftp ${fdtaddr} am335x/${fdtfile}
+	U-Boot # run mmcargs
+	U-Boot # spl export fdt 81000000 - ${fdtaddr}
+	# Write the updated device tree to MMC
+	U-Boot # mmc write ${fdtaddr} 80 80
+	# Write the uImage to MMC
+	U-Boot # mmc write 81000000 900 2000
+
+Falcon Mode: FAT SD cards
+-------------------------
+
+In this case the additional file is written to the filesystem.  In this
+example we assume that the uImage and device tree to be used are already on
+the FAT filesystem (only the uImage MUST be for this to function
+afterwards) along with a Falcon Mode aware MLO and the FAT partition has
+already been created and marked bootable:
+
+.. code-block:: text
+
+	U-Boot # mmc rescan
+	# Load kernel and device tree into memory, perform export
+	U-Boot # load mmc 0:1 ${loadaddr} uImage
+	U-Boot # run findfdt
+	U-Boot # load mmc 0:1 ${fdtaddr} ${fdtfile}
+	U-Boot # run mmcargs
+	U-Boot # spl export fdt ${loadaddr} - ${fdtaddr}
+
+This will print a number of lines and then end with something like:
+
+.. code-block:: text
+
+           Using Device Tree in place at 80f80000, end 80f85928
+           Using Device Tree in place at 80f80000, end 80f88928
+
+So then you:
+
+.. code-block:: text
+
+        U-Boot # fatwrite mmc 0:1 0x80f80000 args 8928
+
+Falcon Mode: NAND
+-----------------
+
+In this case the additional data is written to another partition of the
+NAND.  In this example we assume that the uImage and device tree to be are
+already located on the NAND somewhere (such as filesystem or mtd partition)
+along with a Falcon Mode aware MLO written to the correct locations for
+booting and mtdparts have been configured correctly for the board:
+
+.. code-block:: text
+
+	U-Boot # nand read ${loadaddr} kernel
+	U-Boot # load nand rootfs ${fdtaddr} /boot/am335x-evm.dtb
+	U-Boot # run nandargs
+	U-Boot # spl export fdt ${loadaddr} - ${fdtaddr}
+	U-Boot # nand erase.part u-boot-spl-os
+	U-Boot # nand write ${fdtaddr} u-boot-spl-os
diff --git a/doc/board/ti/index.rst b/doc/board/ti/index.rst
index c0da04b..014a097 100644
--- a/doc/board/ti/index.rst
+++ b/doc/board/ti/index.rst
@@ -6,4 +6,5 @@ Texas Instruments
 .. toctree::
    :maxdepth: 2
 
+   am335x_evm
    j721e_evm
-- 
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